Your search keyword '"Tickle C"' showing total 27 results

1. Dimeric combinations of MafB, cFos and cJun control the apoptosis-survival balance in limb morphogenesis.

Author

Suda N, Itoh T, Nakato R, Shirakawa D, Bando M, Katou Y, Kataoka K, Shirahige K, Tickle C, and Tanaka M

Subjects

Animals, Binding Sites, Bone Morphogenetic Proteins metabolism, Cell Survival, Chick Embryo, Chickens, Down-Regulation genetics, Gene Expression Profiling, Gene Expression Regulation, Developmental, Limb Buds cytology, Limb Buds embryology, Limb Buds metabolism, Macrophages metabolism, MafB Transcription Factor genetics, Models, Biological, Protein Binding, Proto-Oncogene Proteins c-fos genetics, Proto-Oncogene Proteins c-jun genetics, Signal Transduction genetics, Transcription Factor AP-1 metabolism, Tretinoin metabolism, Apoptosis, Extremities embryology, MafB Transcription Factor metabolism, Morphogenesis genetics, Protein Multimerization, Proto-Oncogene Proteins c-fos metabolism, Proto-Oncogene Proteins c-jun metabolism

Abstract

Apoptosis is an important mechanism for sculpting morphology. However, the molecular cascades that control apoptosis in developing limb buds remain largely unclear. Here, we show that MafB was specifically expressed in apoptotic regions of chick limb buds, and MafB/cFos heterodimers repressed apoptosis, whereas MafB/cJun heterodimers promoted apoptosis for sculpting the shape of the limbs. Chromatin immunoprecipitation sequencing in chick limb buds identified potential target genes and regulatory elements controlled by Maf and Jun. Functional analyses revealed that expression of p63 and p73, key components known to arrest the cell cycle, was directly activated by MafB and cJun. Our data suggest that dimeric combinations of MafB, cFos and cJun in developing chick limb buds control the number of apoptotic cells, and that MafB/cJun heterodimers lead to apoptosis via activation of p63 and p73., (© 2014. Published by The Company of Biologists Ltd.)

Published

2014

2. Generation of mice with functional inactivation of talpid3, a gene first identified in chicken.

Author

Bangs F, Antonio N, Thongnuek P, Welten M, Davey MG, Briscoe J, and Tickle C

Subjects

Animals, Chick Embryo, Cilia metabolism, Embryo, Mammalian abnormalities, Embryo, Mammalian anatomy & histology, Embryo, Mammalian physiology, Female, Gene Expression Regulation, Developmental, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Limb Buds abnormalities, Limb Buds physiology, Mice, Mice, Inbred BALB C, Mice, Inbred C57BL, Mice, Knockout, Osteogenesis physiology, Signal Transduction physiology, Chickens genetics, Limb Buds anatomy & histology, Limb Buds embryology, Morphogenesis genetics, Proteins genetics, Proteins metabolism

Abstract

Specification of digit number and identity is central to digit pattern in vertebrate limbs. The classical talpid(3) chicken mutant has many unpatterned digits together with defects in other regions, depending on hedgehog (Hh) signalling, and exhibits embryonic lethality. The talpid(3) chicken has a mutation in KIAA0586, which encodes a centrosomal protein required for the formation of primary cilia, which are sites of vertebrate Hh signalling. The highly conserved exons 11 and 12 of KIAA0586 are essential to rescue cilia in talpid(3) chicken mutants. We constitutively deleted these two exons to make a talpid3(-/-) mouse. Mutant mouse embryos lack primary cilia and, like talpid(3) chicken embryos, have face and neural tube defects but also defects in left/right asymmetry. Conditional deletion in mouse limb mesenchyme results in polydactyly and in brachydactyly and a failure of subperisoteal bone formation, defects that are attributable to abnormal sonic hedgehog and Indian hedgehog signalling, respectively. Like talpid(3) chicken limbs, the mutant mouse limbs are syndactylous with uneven digit spacing as reflected in altered Raldh2 expression, which is normally associated with interdigital mesenchyme. Both mouse and chicken mutant limb buds are broad and short. talpid3(-/-) mouse cells migrate more slowly than wild-type mouse cells, a change in cell behaviour that possibly contributes to altered limb bud morphogenesis. This genetic mouse model will facilitate further conditional approaches, epistatic experiments and open up investigation into the function of the novel talpid3 gene using the many resources available for mice.

Published

2011

3. Interactions between Shh, Sostdc1 and Wnt signaling and a new feedback loop for spatial patterning of the teeth.

Author

Cho SW, Kwak S, Woolley TE, Lee MJ, Kim EJ, Baker RE, Kim HJ, Shin JS, Tickle C, Maini PK, and Jung HS

Subjects

Adaptor Proteins, Signal Transducing, Animals, Body Patterning physiology, Bone Morphogenetic Proteins genetics, Bone Morphogenetic Proteins metabolism, Cells, Cultured, Computer Simulation, Embryo, Mammalian, Epistasis, Genetic physiology, Hedgehog Proteins genetics, Hedgehog Proteins metabolism, Mice, Mice, Knockout, Mice, Nude, Models, Theoretical, Odontogenesis genetics, Odontogenesis physiology, Signal Transduction genetics, Signal Transduction physiology, Tooth metabolism, Wnt Proteins genetics, Wnt Proteins metabolism, Body Patterning genetics, Bone Morphogenetic Proteins physiology, Feedback, Physiological physiology, Hedgehog Proteins physiology, Tooth embryology, Wnt Proteins physiology

Abstract

Each vertebrate species displays specific tooth patterns in each quadrant of the jaw: the mouse has one incisor and three molars, which develop at precise locations and at different times. The reason why multiple teeth form in the jaw of vertebrates and the way in which they develop separately from each other have been extensively studied, but the genetic mechanism governing the spatial patterning of teeth still remains to be elucidated. Sonic hedgehog (Shh) is one of the key signaling molecules involved in the spatial patterning of teeth and other ectodermal organs such as hair, vibrissae and feathers. Sostdc1, a secreted inhibitor of the Wnt and Bmp pathways, also regulates the spatial patterning of teeth and hair. Here, by utilizing maternal transfer of 5E1 (an anti-Shh antibody) to mouse embryos through the placenta, we show that Sostdc1 is downstream of Shh signaling and suggest a Wnt-Shh-Sostdc1 negative feedback loop as a pivotal mechanism controlling the spatial patterning of teeth. Furthermore, we propose a new reaction-diffusion model in which Wnt, Shh and Sostdc1 act as the activator, mediator and inhibitor, respectively, and confirm that such interactions can generate the tooth pattern of a wild-type mouse and can explain the various tooth patterns produced experimentally.

Published

2011

4. The Talpid3 gene (KIAA0586) encodes a centrosomal protein that is essential for primary cilia formation.

Author

Yin Y, Bangs F, Paton IR, Prescott A, James J, Davey MG, Whitley P, Genikhovich G, Technau U, Burt DW, and Tickle C

Subjects

Actins metabolism, Amino Acid Sequence, Animals, Avian Proteins chemistry, Avian Proteins metabolism, Body Patterning, Centrosome ultrastructure, Chick Embryo, Cilia ultrastructure, Computational Biology, Microtubules ultrastructure, Molecular Sequence Data, Mutation genetics, Neural Tube cytology, Neural Tube embryology, Protein Structure, Tertiary, Protein Transport, Sequence Alignment, Subcellular Fractions metabolism, Avian Proteins genetics, Centrosome metabolism, Chickens metabolism, Cilia metabolism, Organogenesis

Abstract

The chicken talpid(3) mutant, with polydactyly and defects in other embryonic regions that depend on hedgehog (Hh) signalling (e.g. the neural tube), has a mutation in KIAA0568. Similar phenotypes are seen in mice and in human syndromes with mutations in genes that encode centrosomal or intraflagella transport proteins. Such mutations lead to defects in primary cilia, sites where Hh signalling occurs. Here, we show that cells of talpid(3) mutant embryos lack primary cilia and that primary cilia can be rescued with constructs encoding Talpid3. talpid(3) mutant embryos also develop polycystic kidneys, consistent with widespread failure of ciliogenesis. Ultrastructural studies of talpid(3) mutant neural tube show that basal bodies mature but fail to dock with the apical cell membrane, are misorientated and almost completely lack ciliary axonemes. We also detected marked changes in actin organisation in talpid(3) mutant cells, which may explain misorientation of basal bodies. KIAA0586 was identified in the human centrosomal proteome and, using an antibody against chicken Talpid3, we detected Talpid3 in the centrosome of wild-type chicken cells but not in mutant cells. Cloning and bioinformatic analysis of the Talpid3 homolog from the sea anemone Nematostella vectensis identified a highly conserved region in the Talpid3 protein, including a predicted coiled-coil domain. We show that this region is required to rescue primary cilia formation and neural tube patterning in talpid(3) mutant embryos, and is sufficient for centrosomal localisation. Thus, Talpid3 is one of a growing number of centrosomal proteins that affect both ciliogenesis and Hh signalling.

Published

2009

5. Growing models of vertebrate limb development.

Author

Towers M and Tickle C

Subjects

Animals, Body Patterning genetics, Extremities embryology, Gene Expression Regulation, Developmental, Vertebrates embryology, Vertebrates genetics, Wings, Animal embryology, Extremities growth & development, Models, Biological, Vertebrates growth & development

Abstract

The developing limb has been a very influential system for studying pattern formation in vertebrates. In the past, classical embryological models have explained how patterned structures are generated along the two principal axes of the limb: the proximodistal (shoulder to finger) and anteroposterior (thumb to little finger) axes. Over time, the genetic and molecular attributes of these patterning models have been discovered, while the role of growth in the patterning process has been only recently highlighted. In this review, we discuss these recent findings and propose how the various models of limb patterning can be reconciled.

Published

2009

6. Autoregulation of Shh expression and Shh induction of cell death suggest a mechanism for modulating polarising activity during chick limb development.

Author

Sanz-Ezquerro JJ and Tickle C

Subjects

Animals, Body Patterning genetics, Body Patterning physiology, Chick Embryo, Extremities embryology, Gene Expression Regulation, Developmental, Hedgehog Proteins, Homeostasis, In Situ Hybridization, Models, Biological, Signal Transduction, Apoptosis genetics, Apoptosis physiology, Proteins genetics, Proteins physiology, Trans-Activators

Abstract

The polarising region expresses the signalling molecule sonic hedgehog (Shh), and is an embryonic signalling centre essential for outgrowth and patterning of the vertebrate limb. Previous work has suggested that there is a buffering mechanism that regulates polarising activity. Little is known about how the number of Shh-expressing cells is controlled but, paradoxically, the polarising region appears to overlap with the posterior necrotic zone, a region of programmed cell death. We have investigated how Shh expression and cell death respond when levels of polarising activity are altered, and show an autoregulatory effect of Shh on Shh expression and that Shh affects cell death in the posterior necrotic zone. When we increased Shh signalling, by grafting polarising region cells or applying Shh protein beads, this led to a reduction in the endogenous Shh domain and an increase in posterior cell death. In contrast, cells in other necrotic regions of the limb bud, including the interdigital areas, were rescued from death by Shh protein. Application of Shh protein to late limb buds also caused alterations in digit morphogenesis. When we reduced the number of Shh-expressing cells in the polarising region by surgery or drug-induced killing, this led to an expansion of the Shh domain and a decrease in the number of dead cells. Furthermore, direct prevention of cell death using a retroviral vector expressing Bcl2 led to an increase in Shh expression. Finally, we provide evidence that the fate of some of the Shh-expressing cells in the polarising region is to undergo apoptosis and contribute to the posterior necrotic zone during normal limb development. Taken together, these results show that there is a buffering system that regulates the number of Shh-expressing cells and thus polarising activity during limb development. They also suggest that cell death induced by Shh could be the cellular mechanism involved. Such an autoregulatory process based on cell death could represent a general way for regulating patterning signals in embryos.

Published

2000

7. Distribution of polarizing activity and potential for limb formation in mouse and chick embryos and possible relationships to polydactyly.

Author

Tanaka M, Cohn MJ, Ashby P, Davey M, Martin P, and Tickle C

Subjects

Animals, Cell Differentiation drug effects, Chick Embryo, Ectoderm metabolism, Embryo, Nonmammalian drug effects, Embryo, Nonmammalian metabolism, Extremities pathology, Fibroblast Growth Factor 4, Fibroblast Growth Factors pharmacology, Gene Expression Regulation, Developmental, Hedgehog Proteins, Immunohistochemistry, In Situ Hybridization, Limb Buds metabolism, Limb Buds transplantation, Mice, Mice, Inbred Strains, Models, Biological, Neck embryology, Proteins metabolism, Proto-Oncogene Proteins pharmacology, Tail embryology, Wings, Animal embryology, Body Patterning drug effects, Extremities embryology, Polydactyly metabolism, Trans-Activators

Abstract

A central feature of the tetrapod body plan is that two pairs of limbs develop at specific positions along the head-to-tail axis. However, the potential to form limbs in chick embryos is more widespread. This could have implications for understanding the basis of limb abnormalities. Here we extend the analysis to mouse embryos and examine systematically the potential of tissues in different regions outside the limbs to contribute to limb structures. We show that the ability of ectoderm to form an apical ridge in response to FGF4 in both mouse and chick embryos exists throughout the flank as does ability of mesenchyme to provide a polarizing region signal. In addition, neck tissue has weak polarizing activity. We show, in chick embryos, that polarizing activity of tissues correlates with the ability either to express Shh or to induce Shh expression. We also show that cells from chick tail can give rise to limb structures. Taken together these observations suggest that naturally occurring polydactyly could involve recruitment of cells from regions adjacent to the limb buds. We show that cells from neck, flank and tail can migrate into limb buds in response to FGF4, which mimics extension of the apical ectodermal ridge. Furthermore, when we apply simultaneously a polarizing signal and a limb induction signal to early chick flank, this leads to limb duplications.

Published

2000

8. A model for anteroposterior patterning of the vertebrate limb based on sequential long- and short-range Shh signalling and Bmp signalling.

Author

Drossopoulou G, Lewis KE, Sanz-Ezquerro JJ, Nikbakht N, McMahon AP, Hofmann C, and Tickle C

Subjects

Animals, Body Patterning drug effects, Body Patterning genetics, Bone Morphogenetic Protein 2, Bone Morphogenetic Proteins genetics, Bone Morphogenetic Proteins pharmacology, Chick Embryo, Hedgehog Proteins, In Situ Hybridization, Membrane Proteins genetics, Membrane Proteins physiology, Patched Receptors, Proteins genetics, Proteins pharmacology, Receptors, Cell Surface, Signal Transduction, Wings, Animal embryology, Body Patterning physiology, Bone Morphogenetic Proteins physiology, Extremities embryology, Models, Biological, Proteins physiology, Trans-Activators, Transforming Growth Factor beta

Abstract

It has been proposed that digit identity in chick limb bud is specified in a dose-dependent fashion by a long-range morphogen, produced by the polarising region. One candidate is Sonic hedgehog (Shh) protein, but it is not clear whether Shh acts long or short range or via Bmps. Here we dissect the relationship between Shh and Bmp signalling. We show that Shh is necessary not only for initiating bmp2 expression but also for sustaining its expression during the period when additional digits are being specified. We also show that we can reproduce much of the effect of Shh during this period by applying only Bmp2. We further demonstrate that it is Bmps that are responsible for digit specification by transiently adding Noggin or Bmp antibodies to limbs treated with Shh. In such limbs, multiple additional digits still form but they all have the same identity. We also explored time dependency and range of Shh signalling by examining ptc expression. We show that high-level ptc expression is induced rapidly when either Shh beads or polarising regions are grafted to a host limb. Furthermore, we find that high-level ptc expression is first widespread but later more restricted. All these data lead us to propose a new model for digit patterning. We suggest that Shh initially acts long range to prime the region of the limb competent to form digits and thus control digit number. Then later, Shh acts short range to induce expression of Bmps, whose morphogenetic action specifies digit identity.

Published

2000

9. Expression of ptc and gli genes in talpid3 suggests bifurcation in Shh pathway.

Author

Lewis KE, Drossopoulou G, Paton IR, Morrice DR, Robertson KE, Burt DW, Ingham PW, and Tickle C

Subjects

Animals, Bone Morphogenetic Protein 2, Bone Morphogenetic Proteins genetics, COUP Transcription Factors, Chick Embryo, Chromosome Mapping, DNA-Binding Proteins genetics, Gene Expression Regulation, Developmental, Genes, Lethal, Hedgehog Proteins, In Situ Hybridization, Limb Buds embryology, Membrane Proteins, Mutation, Oncogene Proteins genetics, Patched Receptors, Phenotype, Polymerase Chain Reaction, Polymorphism, Single-Stranded Conformational, Receptors, Cell Surface genetics, Signal Transduction, Tissue Transplantation, Transcription Factors genetics, Zinc Finger Protein GLI1, Proteins genetics, Receptors, G-Protein-Coupled, Receptors, Steroid, Trans-Activators, Transforming Growth Factor beta

Abstract

talpid3 is an embryonic-lethal chicken mutation in a molecularly un-characterised autosomal gene. The recessive, pleiotropic phenotype includes polydactylous limbs with morphologically similar digits. Previous analysis established that hox-D and bmp genes, that are normally expressed posteriorly in the limb bud in response to a localised, posterior source of Sonic Hedgehog (Shh) are expressed symmetrically across the entire anteroposterior axis in talpid3 limb buds. In contrast, Shh expression itself is unaffected. Here we examine expression of patched (ptc), which encodes a component of the Shh receptor, and is probably itself a direct target of Shh signalling, to establish whether talpid3 acts in the Shh pathway. We find that ptc expression is significantly reduced in talpid3 embryos. We also demonstrate that talpid3 function is not required for Shh signal production but is required for normal response to Shh signals, implicating talpid3 in transduction of Shh signals in responding cells. Our analysis of expression of putative components of the Shh pathway, gli1, gli3 and coupTFII shows that genes regulated by Shh are either ectopically expressed or no longer responsive to Shh signals in talpid3 limbs, suggesting possible bifurcation in the Shh pathway. We also describe genetic mapping of gli1, ptc, shh and smoothened in chickens and confirm by co-segregation analysis that none of these genes correspond to talpid3.

Published

1999

10. Tbx genes and limb identity in chick embryo development.

Author

Isaac A, Rodriguez-Esteban C, Ryan A, Altabef M, Tsukui T, Patel K, Tickle C, and Izpisúa-Belmonte JC

Subjects

Amino Acid Sequence, Animals, Chick Embryo, Cloning, Molecular, Embryonic Induction, Fibroblast Growth Factor 2 pharmacology, Genes, Regulator genetics, Hindlimb transplantation, Limb Buds, Mice, Molecular Sequence Data, RNA, Messenger analysis, Sequence Homology, Amino Acid, Wings, Animal transplantation, Avian Proteins, Gene Expression Regulation, Developmental physiology, Hindlimb embryology, T-Box Domain Proteins, Transcription Factors genetics, Wings, Animal embryology

Abstract

Tbx-2, Tbx-3, Tbx-4 and Tbx-5 chick genes have been isolated and, like the mouse homologues, are expressed in the limb regions. Tbx-2 and Tbx-3 are expressed in anterior and posterior domains in wings and legs, as well as throughout the flank. Of particular interest, however, are Tbx-5, which is expressed in wing and flank but not leg, and Tbx-4, which is expressed very strongly in leg but not wing. Grafts of leg tissue to wing and wing tissue to leg give rise to toe-like or wing-like digits in wing and leg respectively. Expression of Tbx-4 is stable when leg tissue is grafted to wing, and Tbx-5 expression is stable when wing tissue is grafted to leg. Induction of either extra wings or legs from the flank by applying FGF-2 in different positions alters the expression of Tbx-4 and Tbx-5 in such a way that suggests that the amount of Tbx-4 that is expressed in the limb determines the type that will form. The ectopic limb always displays a limb-like Tbx-3 expression. Thus Tbx-4 and Tbx-5 are strong candidates for encoding 'wingness' and 'legness'.

Published

1998

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

Author

Altabef M, Clarke JD, and Tickle C

Subjects

Animals, Chick Embryo, Embryonic Induction, Genes, Homeobox, Mesoderm cytology, Models, Biological, Signal Transduction, Ectoderm cytology, Extremities embryology

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

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

Author

Yang Y, Drossopoulou G, Chuang PT, Duprez D, Marti E, Bumcrot D, Vargesson N, Clarke J, Niswander L, McMahon A, and Tickle C

Subjects

Animals, Body Patterning, CD4 Antigens genetics, CD4 Antigens metabolism, COS Cells metabolism, Cell Membrane metabolism, Chick Embryo, Dose-Response Relationship, Drug, Gene Expression Regulation, Developmental drug effects, Hedgehog Proteins, Proteins pharmacology, Recombinant Proteins genetics, Recombinant Proteins metabolism, Wings, Animal drug effects, Proteins physiology, Signal Transduction, Trans-Activators, Wings, Animal embryology

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 long-range 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 microm 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

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

Author

Nittenberg R, Patel K, Joshi Y, Krumlauf R, Wilkinson DG, Brickell PM, Tickle C, and Clarke JD

Subjects

Animals, Chick Embryo, Cranial Nerves physiology, Cranial Nerves ultrastructure, DNA-Binding Proteins genetics, Early Growth Response Protein 2, Embryonic Induction drug effects, Homeodomain Proteins genetics, Motor Neurons physiology, Motor Neurons ultrastructure, Neurons drug effects, Neuropeptides genetics, Receptor Protein-Tyrosine Kinases genetics, Receptor, EphA4, Rhombencephalon drug effects, Transcription Factors genetics, Tretinoin pharmacology, Cell Movement drug effects, Gene Expression Regulation, Developmental, Neurons physiology, Rhombencephalon cytology, Rhombencephalon embryology

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

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

Author

Vargesson N, Clarke JD, Vincent K, Coles C, Wolpert L, and Tickle C

Subjects

Animals, Carbocyanines, Chick Embryo, Fibroblast Growth Factor 4, Fibroblast Growth Factors genetics, Fluorescent Dyes, Homeodomain Proteins genetics, Limb Buds, Proto-Oncogene Proteins genetics, Pyridinium Compounds, Wings, Animal embryology, Body Patterning genetics, Ectoderm cytology, Gene Expression Regulation, Developmental, Mesoderm cytology, 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 relationship 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.

Published

1997

15. Activation of Fgf-4 and HoxD gene expression by BMP-2 expressing cells in the developing chick limb.

Author

Duprez DM, Kostakopoulou K, Francis-West PH, Tickle C, and Brickell PM

Subjects

Animals, Bone Morphogenetic Proteins, Cell Line, Chick Embryo, Culture Techniques, Fibroblast Growth Factor 4, Hedgehog Proteins, Humans, Limb Buds, Proteins genetics, Quail, Signal Transduction, Transfection, Wings, Animal embryology, Fibroblast Growth Factors genetics, Gene Expression Regulation, Developmental, Homeodomain Proteins genetics, Proteins physiology, Proto-Oncogene Proteins genetics, Trans-Activators, Transcription Factors genetics

Abstract

Bone morphogenetic protein-2 (BMP-2) has been implicated in the polarizing region signalling pathway, which specifies pattern across the antero-posterior of the developing vertebrate limb. Retinoic acid and Sonic Hedgehog (SHH) can act as polarizing signals; when applied anteriorly in the limb bud, they induce mirror-image digit duplications and ectopic Bmp-2 expression in anterior mesenchyme. In addition, the two signals can activate Fgf-4 expression in anterior ridge and HoxD expression in anterior mesenchyme. We tested the role of BMP-2 in this signalling cascade by ectopically expressing human BMP-2 (hBMP-2) at the anterior margin of the early wing bud using a replication defective retroviral vector, and found that ectopic expression of Fgf-4 was induced in the anterior part of the apical ectodermal ridge, followed later by ectopic expression of Hoxd-11 and Hoxd-13 in anterior mesenchyme. This suggests that BMP-2 is involved in regulating Fgf-4 and HoxD gene expression in the normal limb bud. Ectopically expressed hBMP-2 also induced duplication of digit 2 and bifurcation of digit 3, but could not produce the mirror-image digit duplications obtained with SHH-expressing cells. These results suggest that BMP-2 may be involved primarily in maintenance of the ridge, and in the link between patterning and outgrowth of the limb bud.

Published

1996

16. Expression and regulation of Cek-8, a cell to cell signalling receptor in developing chick limb buds.

Author

Patel K, Nittenberg R, D'Souza D, Irving C, Burt D, Wilkinson DG, and Tickle C

Subjects

Animals, Bone Morphogenetic Proteins, Cell Communication, Chick Embryo, Feathers embryology, Fibroblast Growth Factor 2 pharmacology, Gene Expression Regulation, Developmental drug effects, Growth Substances pharmacology, Limb Buds cytology, Limb Buds growth & development, Mesoderm chemistry, Mice, Mice, Inbred C57BL, Microspheres, Mutation, Proteins pharmacology, RNA, Messenger analysis, Receptor, EphA4, Tendons chemistry, Tendons embryology, Tretinoin pharmacology, Gene Expression Regulation, Developmental physiology, Limb Buds physiology, Neuropeptides genetics, Receptor Protein-Tyrosine Kinases genetics

Abstract

The Eph-related receptor tyrosine kinase gene, Cek-8, is expressed in mesenchyme at the tip of chick limb buds, with high levels of transcripts posteriorly and apically but fading out anteriorly. Expression of Cek-8 in distal mesenchyme is regulated by apical ridge- and FGF-polarising signals and retinoic acid, and is uniform across the anteroposterior axis in talpid3 mutants. These data indicate that Cek-8 expression responds to regulatory signals during limb patterning and suggest that this receptor tyrosine kinase may have a role in coordinating responses to signals in the progress zone of early buds. Later on in limb development, Cek-8 expression is associated with cell condensations that form tendons and their attachments to cartilage rudiments and then in developing feather buds.

Published

1996

17. Tissue and cellular patterning of the musculature in chick wings.

Author

Robson LG, Kara T, Crawley A, and Tickle C

Subjects

Animals, Cells, Cultured, Morphogenesis physiology, Muscles cytology, Muscles drug effects, Tretinoin pharmacology, Chick Embryo physiology, Muscles embryology, Wings, Animal embryology

Abstract

Development of the musculature involves generation of a precise number of individual muscles arranged in appropriate locations, each with the correct cellular patterning. To find out the rules that govern muscle number and arrangement, the forearm musculature of chick wing buds was analysed following grafts of the polarizing region or application of retinoic acid. Muscle patterns appear symmetrical with 'posterior' muscles now forming in the anterior part of the wing. When the number of muscles that develop is reduced, pattern symmetry is maintained, with loss of anterior muscles in the mid-line, especially dorsally. Strict anteroposterior ordering of muscles in duplicated patterns does not always occur. The number of muscles that develops bears some relationship to the number of forearm elements. Each muscle has a characteristic pattern of fast and slow fibres. In duplicated wings, each pair of symmetrically arranged muscles has the same fibre type pattern. Not only are proportions of fast and slow fibres similar, but local variations in fibre type arrangement within the muscle are also reproduced. This suggests that the cellular pattern within the new 'posterior' muscles at the anterior of the limb has been re-specified. In manipulated limb buds, which will develop a duplicated muscle pattern, there are no detectable changes in distribution and number of potentially myogenic cells, and fibre type patterning within early muscle masses also appears normal. In contrast, the splitting process that divides up muscle masses is altered. The appropriate fibre type arrangement only emerges after splitting is complete. This suggests that tissue patterning and cellular patterning occur at different times during muscle development.

Published

1994

18. Bone morphogenetic proteins and a signalling pathway that controls patterning in the developing chick limb.

Author

Francis PH, Richardson MK, Brickell PM, and Tickle C

Subjects

Amino Acid Sequence, Animals, Blotting, Northern, Bone Morphogenetic Proteins, Chick Embryo, Gene Expression drug effects, Humans, In Situ Hybridization, Fluorescence, Mice, Molecular Sequence Data, Morphogenesis physiology, Proteins genetics, Sequence Homology, Amino Acid, Tretinoin pharmacology, Growth Substances physiology, Proteins physiology, Wings, Animal embryology

Abstract

We show here that bone morphogenetic protein 2 (BMP-2) is involved in patterning the developing chick limb. During early stages of limb development, mesenchymal expression of the Bmp-2 gene is restricted to the posterior part of the bud, in a domain that colocalizes with the polarizing region. The polarizing region is a group of cells at the posterior margin of the limb bud that can respecify the anteroposterior axis of the limb when grafted anteriorly and can activate expression of genes of the HoxD complex. We dissect possible roles of BMP-2 in the polarizing region signalling pathway by manipulating the developing wing bud. Retinoic acid application, which mimics the effects of polarizing region grafts, activates Bmp-2 gene expression in anterior cells. This shows that changes in anteroposterior pattern are correlated with changes in Bmp-2 expression. When polarizing region grafts are placed at the anterior margin of the wing bud, the grafts continue to express the Bmp-2 gene and also activate Bmp-2 expression in the adjacent anterior host mesenchyme. These data suggest that BMP-2 is part of the response pathway to the polarizing signal, rather than being the signal itself. In support of this, BMP-2 protein does not appear to have any detectable polarizing activity when applied to the wing bud. The pattern of Bmp-4 gene expression in the developing wing bud raises the possibility that BMP-2 and BMP-4 could act in concert. There is a close relationship, both temporal and spatial, between the activation of the Bmp-2 and Hoxd-13 genes in response to retinoic acid and polarizing region grafts, suggesting that expression of the two genes might be linked.

Published

1994

19. FGF-4 maintains polarizing activity of posterior limb bud cells in vivo and in vitro.

Author

Vogel A and Tickle C

Subjects

Animals, Cells, Cultured, Chick Embryo, Embryonic Induction drug effects, Fibroblast Growth Factor 4, Fibroblast Growth Factors pharmacology, Mesoderm cytology, Mice, Morphogenesis drug effects, Morphogenesis physiology, Proto-Oncogene Proteins pharmacology, Ectoderm physiology, Embryonic Induction physiology, Extremities embryology, Fibroblast Growth Factors physiology, Proto-Oncogene Proteins physiology

Abstract

The polarizing region is a major signalling tissue involved in patterning the tissues of the vertebrate limb. The polarizing region is located at the posterior margin of the limb bud and can be recognized by its ability to induce additional digits when grafted to the anterior margin of a chick limb bud. The signal from the polarizing region operates at the tip of the bud in the progress zone, a zone of undifferentiated mesenchymal cells, maintained by interactions with the apical ectodermal ridge. A number of observations have pointed to a link between the apical ectodermal ridge and signalling by the polarizing region. To test this possibility, we removed the posterior apical ectodermal ridge of chick wing buds and assayed posterior mesenchyme for polarizing activity. When the apical ectodermal ridge is removed, there is a marked decrease in polarizing activity of posterior cells. The posterior apical ectodermal ridge is known to express FGF-4 and we show that the decrease in polarizing activity of posterior cells of wing buds that normally follows ridge removal can be prevented by implanting a FGF-4-soaked bead. Furthermore, we show that both ectoderm and FGF-4 maintain polarizing activity of limb bud cells in culture.

Published

1993

20. Experimental analysis of the control of expression of the homeobox-gene Msx-1 in the developing limb and face.

Author

Brown JM, Wedden SE, Millburn GH, Robson LG, Hill RE, Davidson DR, and Tickle C

Subjects

Animals, Chick Embryo, Gene Expression genetics, In Situ Hybridization, Mesoderm physiology, Mesoderm transplantation, Mice, Extremities embryology, Face embryology, Gene Expression Regulation physiology, Genes, Homeobox genetics

Abstract

Mouse mesenchyme was grafted into chick embryos to investigate the control of mesenchymal expression of Msx-1 in the developing limb and face. In situ hybridization, using species-specific probes, allows a comparison between Msx-1 expression in the graft and the host tissue. The results show that Msx-1 expression in both limb-to-limb and face-to-face grafts corresponds closely with the level of Msx-1 expression in the surrounding chick mesenchyme. Cells in grafts that end up within the host domain of Msx-1 express the gene irrespective of whether they were from normally expressing, or non-expressing, regions. Therefore Msx-1 expression in both the developing limb and the developing face appears to be position-dependent. Mesenchyme from each of the three major facial primordia behaved in the same way when grafted to the chick maxillary primordium. Reciprocal grafts between face and limb gave a different result: Msx-1 expression was activated when facial mesenchyme was grafted to the limb but not when limb mesenchyme was grafted to the face. This suggests either that there are quantitative or qualitative differences in two local signalling systems or that additional factors determine the responsiveness of the mesenchyme cells.

Published

1993

21. Hox-4 gene expression in mouse/chicken heterospecific grafts of signalling regions to limb buds reveals similarities in patterning mechanisms.

Author

Izpisúa-Belmonte JC, Brown JM, Crawley A, Duboule D, and Tickle C

Subjects

Animals, Central Nervous System embryology, Chick Embryo, Extremities transplantation, Gene Expression, Mice, Morphogenesis genetics, Extremities embryology, Gastrula physiology, Genes, Homeobox genetics

Abstract

The products of Hox-4 genes appear to encode position in developing vertebrate limbs. In chick embryos, a number of different signalling regions when grafted to wing buds lead to duplicated digit patterns. We grafted tissue from the equivalent regions in mouse embryos to chick wing buds and assayed expression of Hox-4 genes in both the mouse cells in the grafts and in the chick cells in the responding limb bud using species specific probes. Tissue from the mouse limb polarizing region and anterior primitive streak respecify anterior chick limb bud cells to give posterior structures and lead to activation of all the genes in the complex. Mouse neural tube and genital tubercle grafts, which give much less extensive changes in pattern, do not activate 5'-located Hox-4 genes. Analysis of expression of Hox-4 genes in mouse cells in the grafted signalling regions reveals no relationship between expression of these genes and strength of their signalling activity. Endogenous signals in the chick limb bud activate Hox-4 genes in grafts of mouse anterior limb cells when placed posteriorly and in grafts of mouse anterior primitive streak tissue. The activation of the same gene network by different signalling regions points to a similarity in patterning mechanisms along the axes of the vertebrate body.

Published

1992

22. The mis-expression of posterior Hox-4 genes in talpid (ta3) mutant wings correlates with the absence of anteroposterior polarity.

Author

Izpisúa-Belmonte JC, Ede DA, Tickle C, and Duboule D

Subjects

Animals, Chick Embryo, Gene Expression, Homozygote, Molecular Probe Techniques, Morphogenesis genetics, Mutation genetics, Wings, Animal abnormalities, Genes, Homeobox genetics, Wings, Animal embryology

Abstract

Developing chicken wings homozygous for the talpid (ta3/ta3) mutation are polydactylous and have defects in the establishment of their anteroposterior polarity. We analysed the expression domains of the posteriorly restricted homeobox Hox-4 genes in such mutant wings. The Hox-4 genes are now expressed right across the anteroposterior axis instead of being expressed just posteriorly. This correlates well with the absence of clear morphological differences between the talpid3 digits and reinforces the idea that vertebrate Hox-4 genes are involved in setting up the limb anteroposterior asymmetry.

Published

1992

23. The role of gap junctions in patterning of the chick limb bud.

Author

Allen F, Tickle C, and Warner A

Subjects

Animals, Cell Communication, Cell Division, Cells, Cultured, Chick Embryo, Connexins, Dimethyl Sulfoxide, Extremities transplantation, Fluorescent Dyes, Freeze Fracturing, Isoquinolines, Membrane Proteins immunology, Morphogenesis, Permeability, Quail, Tretinoin metabolism, Extremities embryology, Intercellular Junctions physiology

Abstract

The role of gap junctional communication during patterning of the chick limb has been investigated. Affinity-purified antibodies raised against rat liver gap junctional proteins were used to block communication between limb mesenchyme cells. Co-injection of the antibodies and Lucifer yellow into mesenchyme cultures demonstrated that communication was inhibited almost immediately. When antibodies were loaded into mesenchyme tissue by DMSO permeabilization, [3H]nucleotide transfer was prevented for at least 16 h. Polarizing region tissue from the posterior limb bud margin causes digit duplications when grafted to the anterior margin. Quail polarizing region cells were loaded with gap junction antibody and grafted into chick wing buds. The antibody had no effect on growth or survival of the grafted cells. As very few polarizing region cells are required to initiate duplications, the number of polarizing region cells in the grafts was reduced by diluting 1:9 with anterior mesenchyme tissue. When either polarizing region or anterior mesenchyme tissue in the graft was loaded separately with antibody, there was little effect on respecification of the digit pattern. However, loading both tissues in the graft caused a significant decrease in duplications. This indicates that a major role of gap junctions in limb patterning may be to enable polarizing region cells to communicate directly with adjacent anterior mesenchyme. A role for gap junctional communication between anterior mesenchyme cells cannot be excluded. The results are discussed in relation to the role of retinoic acid as a putative morphogen.

Published

1990

24. Retinoids reprogramme pre-bud mesenchyme to give changes in limb pattern.

Author

Wilde SM, Wedden SE, and Tickle C

Subjects

Animals, Chick Embryo, Extremities embryology, Morphogenesis, Time Factors, Extremities drug effects, Mesoderm drug effects, Tretinoin pharmacology

Abstract

Retinoic acid was locally applied to presumptive limb regions of chick embryos to find out the earliest time at which the limb pattern can be reprogrammed. When beads soaked in retinoic acid were placed in the appropriate positions in embryos at stage 10 or older, duplicated or reduced leg patterns resulted. To pin point the time at which the cells in the limb rudiment respond to the retinoid, beads were removed at various times and the lengths of exposure required to reprogramme limb development found. The early limb rudiments require longer exposures to give duplications than late rudiments. The effective treatment periods last at least until stage 17 when the limb bud and apical ectodermal ridge develop. In contrast, the length of exposure to reduce the limb is constant at early stages. Retinoids first start acting to produce duplicated structures between stages 10 and 13. Therefore, retinoids appear to begin to reprogramme the cells as soon as they are determined to give rise to a limb.

Published

1987

25. Pattern formation in the facial primordia.

Author

Wedden SE, Ralphs JR, and Tickle C

Subjects

Animals, Cell Differentiation, Chick Embryo, Epithelium physiology, Face ultrastructure, Microscopy, Electron, Retinoids adverse effects, Face embryology, Neural Crest physiology

Abstract

Pattern formation is the developmental process that leads to the spatial ordering of cell differentiation. We have explored the problem of pattern formation in the development of the face of chick embryos. At early stages, the developing face consists of a series of small buds of tissue, the facial primordia that encircle the primitive mouth. The concepts of positional information provide a framework for considering how the patterns of differentiated cells are generated in the face. We suggest that the cranial neural crest cells must first be informed to which facial primordium they belong and then of their position within that primordium. The cells of the early primordia appear indistinguishable. However, when the mesenchyme cells are placed in high-density culture, cartilage differentiates. The extent and pattern of cartilage differentiation is characteristic for the cell population of each facial primordium. Myogenic cells also differentiate in the cultures, but the proportion of myogenic cells is independent of the extent of chondrogenesis. Within the facial primordia, a set of epithelial-mesenchymal interactions appears to be required for outgrowth and pattern formation along the proximodistal axis of the chick beaks. In culture, face epithelium locally inhibits cartilage differentiation and suggests that another set of epithelial-mesenchymal interactions may be involved in cell patterning. The mechanisms involved in specifying the mediolateral axis of the face, for example, the midpoint of the upper beak, are not known. Vitamin A derivatives, collectively known as retinoids, affect the development of the face of chick embryos and lead to a specific facial defect. Upper beak development is inhibited but the lower beak develops normally. The response to retinoids could be related to the specification of cells to belong to the facial primordium that will form the upper beak. Alternatively, retinoids may interfere with positional cues that operate to inform cells of their position within that primordium.

Published

1988

26. Retinoic acid application to chick wing buds leads to a dose-dependent reorganization of the apical ectodermal ridge that is mediated by the mesenchyme.

Author

Tickle C, Crawley A, and Farrar J

Subjects

Animals, Chick Embryo, Ectoderm drug effects, Ectoderm physiology, Ectoderm ultrastructure, Epithelial Cells, Epithelium drug effects, Epithelium ultrastructure, Time Factors, Wings, Animal embryology, Ectoderm cytology, Mesoderm physiology, Tretinoin pharmacology

Abstract

Local application of retinoic acid to wing buds of chick embryos leads to dose- and position-dependent changes in the pattern of cellular differentiation. Early effects of retinoid treatment on the apical ectodermal ridge coordinate pattern changes and morphogenesis. The length of the apical ridge increases when additional digits will form but decreases when digits are lost. These changes in length can be understood in terms of a threshold response to the local retinoid concentration that results in either disappearance or maintenance of the ridge (Lee & Tickle, J. Embryol. exp. Morph. 90, 139-169 (1985)). Here, we have analysed the mechanisms involved in ridge disappearance by locally applying retinoic acid to the apex of stage 20 chick wing buds. With this treatment regime, low doses give duplicated digit patterns and higher doses truncations. The height of the apical ridge is progressively reduced with increasing doses of retinoid and the time course of ridge flattening indicates that the height of the ridge is correlated with bud outgrowth. With high doses of retinoic acid, the typical ridge, a pseudostratified epithelium in which the columnar cells are tightly packed, disappears and the epithelium at the tip of the bud consists of loosely packed cuboidal cells. Shortly after treatment, there is a decrease in the number of gap junctions between ridge cells. This early change in cell contacts suggests that gap junctions may be involved in maintaining epithelial morphology. When treated epithelium is recombined with untreated mesenchyme, an apical ridge is reestablished and distal structures can be generated. In contrast, when treated mesenchyme is recombined with the epithelium from normal buds, only proximal structures are formed. Therefore, retinoids can lead to a reorganization of the apical ectodermal ridge which is mediated and maintained by the mesenchyme.

Published

1989

27. Characterization of epithelial domains in the nasal passages of chick embryos: spatial and temporal mapping of a range of extracellular matrix and cell surface molecules during development of the nasal placode.

Author

Croucher SJ and Tickle C

Subjects

Animals, Biomarkers analysis, Carbohydrates analysis, Cell Membrane ultrastructure, Chick Embryo, Chondroitin Sulfate Proteoglycans analysis, Epithelial Cells, Extracellular Matrix ultrastructure, Fluorescent Antibody Technique, Heparan Sulfate Proteoglycans, Heparitin Sulfate analysis, Keratan Sulfate analysis, Lectins, Nose cytology, Staining and Labeling, Cell Adhesion Molecules, Neuronal analysis, Nose embryology

Abstract

The formation of the nasal passages involves complex morphogenesis and their lining develops a spatially ordered pattern of differentiation, with distinct domains of olfactory and respiratory epithelium. Using antibodies to the neural cell adhesion molecule (N-CAM), keratan sulphate and heparan sulphate proteoglycan (HSPG) and a panel of lectins (agglutinins of Canavalia ensiformis (ConA), Dolichos biflorus (DBA), peanut (PNA), Ricinis communis (RCA1), soybean (SBA), Ulex europaeus (UEA1), and wheatgerm (WGA], we have documented cell surface characteristics of each epithelial domain. Binding of antibodies to N-CAM and to keratan sulphate, and the lectins ConA, PNA, RCA1, SBA and WGA marks the olfactory epithelial domain only. The restriction of N-CAM to the sensory region of the epithelium has also been reported in the developing ear. This striking similarity is consistent with the idea that N-CAM may be involved in the division of functionally and histologically distinct cell groups within an epithelium. We traced the olfactory-specific cell markers during development to gain insights into the origin of the epithelial lining of the nasal passages. All reagents bind at early stages to the thickened nasal placode and surrounding head ectoderm and then become progressively restricted to the olfactory domain. The expression of these characteristics appears to be modulated during development rather than being cell autonomous. The distribution of keratan sulphate was compared with collagen type II in relation to the specification of the chondrocranium. Keratan sulphate and collagen type II are only colocalized at the epithelial-mesenchymal interface during early nasal development. At later stages, only collagen type II is expressed at the interface throughout the nasal passages, whereas keratan sulphate is absent beneath the respiratory epithelium.

Published

1989