Retinoic acid respecifies limb bud cells in vitro.

Retinoic acid (RA) is known to have dramatic effects on limb pattern formation and has been shown to exert its effects on limbs by converting anterior limb bud cells into cells with posterior positional properties. In this study we find that dissociated posterior limb bud cells from chick and mouse embryos cultured at high density (micromass cultures) are able to stimulate the formation of supernumerary digits when grafted into developing wing buds and that the positional identity of both chick and mouse limb bud cells can be maintained for finite periods of time in vitro. Furthermore, using this assay system we have tested whether anterior cells from mouse and chick limb buds can be converted into cells with posterior identity by exposure to RA in vitro. We find that anterior limb bud cells acquire posterior properties after culture in the presence of RA.     

Pattern formation in epithelial development: the vertebrate limb and feather bud spacing.

The ectoderm of the vertebrate limb and feather bud are epithelia that provide good models for epithelial patterning in vertebrate development. At the tip of chick and mouse limb buds is a thickening, the apical ectodermal ridge, which is essential for limb bud outgrowth. The signal from the ridge to the underlying mesoderm involves fibroblast growth factors. The non-ridge ectoderm specifies the dorsoventral pattern of the bud and Wnt7a is a dorsalizing signal. The development of the ridge involves an interaction between dorsal cells that express radical fringe and those that do not. There are striking similarities between the signals and genes involved in patterning the limb ectoderm and the epithelia of the Drosophila imaginal disc that gives rise to the wing. The spacing of feather buds involves signals from the epidermis to the underlying mesenchyme, which again include Wnt7a and fibroblast growth factors.     

Morphogens in chick limb development

Retinoic acid is a good candidate for a morphogen in chick limb bud development. The challenge now is to determine how retinoic acid interacts with limb bud cells and how the retinoic acid signal is integrated with other signals to mould and pattern the developing limb.     

Temporal pattern of posterior positional identity in mouse limb buds

This study describes the temporal pattern of posterior positional identity in mouse limb bud cells. To do this wedges of tissue from the posterior edge of mouse limb buds at various stages (limb stages: Wanek et al., 1989b. J. Exp. Zool. 249, 41-49) were grafted to the anterior edge of a host chick embryo wing bud. Grafts of mouse posterior cells are able to induce the formation of supernumerary digits every time when they are taken from buds from stage 3 through stage 6. At stage 7, the frequency declines and by stage 8 the chick cells no longer respond. The results indicate a change in tissue properties at stage 7, which progresses by stage 8 to the point at which posterior positional identity is no longer detectable by this assay. These temporal changes in this aspect of limb pattern formation can be used as an additional criterion to guide the identification of genes involved in the specification of posterior positional identity.     

Distribution of retinoids in the chick limb bud: analysis with monoclonal antibody

Retinoic acid induces anteroposterior duplicate formation in developing chick limb bud, and it may be a natural morphogen involved in limb pattern formation. Retinoic acid is produced from retinol locally in the limb bud via retinal, and thus, to elucidate the distribution of these retinoids in the limb bud seems to be important for the understanding of the morphogen formation. We produced a monoclonal antibody against the retinoids with BSA-RA (bovine serum albumin-retinoic acid) conjugate for antigen, and investigated the distribution of retinoids in the chick limb bud. The antibody predominantly bound to retinoic acid, but weakly to retinol and retinal. Retinoids appeared in the limb bud at stage 18 and were distributed through stages 20-24, when the pattern formation in distal mesoderm was in progress. Initially they were found evenly in the whole mesoderm, but disappeared gradually from core mesoderm and remained only in the region of peripheral mesoderm at stage 24. At stage 26, retinoids were detected only in ectoderm. These results support the idea that the retinoids actually play roles in limb pattern formation and suggest that the retinoids in the peripheral mesoderm are important for pattern formation. Further, the role of retinoids in epidermis development at later limb bud stages is also suggested.     

Régulation des excédents dans le développement du bourgeon de membre de l'embryon d'oiseau. Analyse expérimentale de combinaisons xénoplastiques caille/poulet

Summary In order to support the demonstration of the regulative capacity of the chick limb bud, already stressed by one of us (Kieny, 1964, 1967), heterospecific combinations were made between chick and quail tissues, the cells of the latter bearing a distinctive nuclear marker. A Japanese quail whole limb bud (stage-18 to 21 of H. H., wing or leg) was grafted distally onto the prospective zeugopod of a chick (stage-22) wing bud sectioned at the prospective wrist level. Thus, from a heterospecific surplus recombinant containing five prospective limb segments (stylopod and zeugopod from the chick host; stylopod, zeugopod and autopod from the quail graft), it was possible to obtain a normally shaped appendage that comprised either upper arm, lower arm and hand in the case of a wing bud graft, or heteromorphic upper arm, lower leg and foot in the case of a hind-limb bud graft. In these cases, regulation for excess appeared to take place mainly within the host tissues. The three proximal segments of the recombinant, namely the chick stylopod and zeugopod of the host's stump and the quail stylopod of the graft, became reorganized and gave rise to a single stylopodial segment, which usually contained a double stylopodial bone element, one of chick, the other of quail origin.The absence of development of the squeezed prospective zeugopod can be interpreted as follows: owing to an interaction with the stylopodial graft tissues, the zeugopodial cells of the juxtaposed stump boundary have shifted proximally their originally more distal positional values, so that they changed their prospective pattern of differentiation to that of stylopod. These reset zeugopodial cells combine with the stylopodial cells of host and graft and form a huge composite stylopod, in which, due to an asynchronous determination in the two species, chick and quail tissues do not cooperate fully for the development of a single bone.

Ce travail a été effectué avec l'aide de la D.G.R.S.T. (Action complémentaire coordonnée: Biologie de la reproduction et du développement, convention n^o 73-7-1661)     

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

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.     

Position of origin of donor posterior chick wing bud tissue transplanted to an anterior host site determines the extra structures formed

The formation of supernumerary limb structures was studied by juxtaposing normally nonadjacent embryonic chick limb bud tissue. Different “wedges” (ectodern and mesoderm) of posterior donor right wing bud (stage 21) were transplanted to a slit made in stage 20–23 host right wing buds. Donor posterior tissue was transplanted to an anterior position in a host wing bud or, as a control, to the same position as its position of origin. Transplanting different wedges of posterior tissue to the same anterior host position results in wings with supernumerary structures, and different extra structures form depending on the position of origin of the donor tissue. The identification of extra limb structures formed was based on the skeletal and integumentary patterns of resulting wings and the pattern of muscles as seen in serial sections of resulting limbs. The results of experiments presented here are considered in light of current models that have been used to describe the formation of supernumerary limb structures by the embryonic chick limb bud.     

Cell adhesiveness and affinity for limb pattern formation

Stage-dependent cell sorting in vitro is an intriguing property that mesenchymal cells of a chick limb bud have. We previously proposed that N-cadherin, a cell adhesion molecule, is involved in the sorting process and is likely to be a component of the mechanism of proximal-distal patterning in the developing limb (Yajima et al., (1999) Dev. Dynam. 216:274-284). Here, we present more direct evidence that N-cadherin is one of the molecules responsible for regulation of stage-dependent cell sorting in vitro. Our results suggest that N-cadherin, which accumulates in the distal region of the chick limb bud as limb development proceeds, is related to the positional identity that gives rise to the different shapes and numbers of cartilaginous elements along the proximal-distal axis. In this article we also give insights into positional identity which is mediated by Hoxgenes and cell surface property during limb development.     

The cellular retinoic-acid-binding protein is expressed in tissues associated with retinoic-acid-induced malformations

Retinoic acid (RA) is thought to play a role in embryonic pattern formation in vertebrates. A naturally occurring gradient of endogenous RA has been demonstrated in the developing chick limb bud, while local application of RA leads to the formation of additional digits. In mammals, a well-defined spectrum of birth defects has been reported as a result of fetal exposure to excess RA. In analogy to the chick limb bud, it may be speculated that these malformations are the result of disturbance of morphogenetic RA concentration gradients. A candidate gene involved in the regulation of endogenous RA concentrations is the gene encoding cellular RA binding protein (CRABP). We have isolated a partial cDNA clone corresponding to the chicken homolog of CRABP, and performed in situ hybridization experiments on sections of embryos at various stages of development. CRABP expression was detected in the CNS, the craniofacial mesenchyme, ganglia of the peripheral nervous system, the limb bud, and the visceral arch area. Our results indicate that the spatiotemporally specified expression pattern displayed by the CRABP gene exhibits a striking correspondence to the tissues that are affected by exposure of avian or mammalian embryos to RA. We hypothesize that CRABP plays an important role in normal embryogenesis and that embryonic tissues showing high CRABP expression are susceptible to the adverse effects of excess RA.     

Inductive activity and enduring cellular constitution of a supernumerary apical ectodermal ridge grafted to the limb bud of the chick embryo.

Apical ectodermal ridges (AERs) isolated from 3- to 4-day chick and quail embryos were prepared by means of trypsinization and microdissection and then were grafted to the dorsal or ventral side of a host chick wing bud. They induced supernumerary limb outgrowths from the host bud showing, respectively, a bidorsal or biventral organization, as determined by the patterns of feather germs. The grafted ridge cells persisted, as revealed by histological sections of supernumerary chick limb parts growing under the influence of quail AERs, whose cells are readily distinguished after application of the Feulgen reagent.These results show that the AER induces limb outgrowth regardless of whether it is associated with dorsal or ventral limb ectoderm and that its continued existence is not dependent on contributions of ectodermal cells from the opposed ectodermal faces of the limb bud. The AER is pictured as maintaining the subjacent mesoderm in a condition of developmental plasticity without specifying its differentiation with respect to the proximodistal axis. It remains uncertain whether the positional values of cells that develop under the influence of the AER arise within these cells themselves or appear in response to influences from proximal sources.     

Feather buds exert a polarizing activity when transplanted to chick limb buds

Homeoproteins have been shown to be expressed in a position-specific manner along the anterior-posterior axis in the developing chick feather bud, as seen also in the developing limb bud. These facts raise the possibility that there may be common mechanistic features in the establishment of the anterior-posterior polarity between both organs. In order to investigate this possibility, feather bud tissues were transplanted into the anterior region of limb buds to determine whether feather bud tissues possess properties such as the zone of polarizing activity of the limb bud. The manipulated limb bud formed a mirror image duplication of the skeletal elements, mainly (2)2234 digit pattern or sometimes 3(2)234. Both the anterior and posterior halves of feather bud tissue exhibited almost equal activity in inducing ectopic skeletal elements. Hox d-12 and Hox a-13 were expressed coordinately around the transplanted site of the operated limb bud. This secondary axis-inducing activity of the feather bud was enhanced when grafts were pretreated with trypsin. In contrast, the presumptive feather bud tissue and inter-feather bud tissue did not induce a secondary axis of the limb bud. These results suggest that the feather bud contains a region that exerts polarizing activity and that this region may play key roles in the formation of the anterior-posterior and, if it exists, proximal-distal axis of the feather bud, possibly via the regulation of region specific expression of Hox genes.     

Pattern regulation in the embryonic chick limb: Supernumerary limb formation with anterior (non-ZPA) limb bud tissue

The formation of supernumerary limbs and limb structures was studied by juxtaposing normally nonadjacent embryonic chick limb bud tissue. A “wedge” (ectoderm and mesoderm) of anterior or mid donor right wing bud (stage 21) was inserted in a slit made in a host right limb bud (stage 21) at the same position as its position of origin or to a more posterior position. The AER of the donor tissue and host wing bud were aligned with each other. Donor tissue was grafted with its dorsalventral polarity the same as the host's limb bud or reversed to that of the host's. Depending on the position of origin of the donor limb bud tissue and the position to which it was transplanted in a host, supernumerary wings or wing structures formed. Furthermore, depending on the orientation of the graft in the host, supernumerary limbs with either left or right asymmetry developed. The results of experiments performed here are considered in light of two current models which have been used to describe supernumerary limb formation: one based on local, short-range, cell-cell interactions and the other based on long-range positional signaling via a diffusible morphogen.     

Distribution of Retinoids Applied Exogenously to Chick Limb Buds: an Autoradiographic Analysis

An autoradiographic analysis was undertaken to examine the localization of retinoids applied exogenously to chick limb buds. Ion-exchange beads (AGI-X2) containing a tritium-labeled synthetic retinoid, Am80, were implanted to various regions of chick wing buds. This synthetic retinoid is known to induce a duplicated limb pattern as retinoic acid (RA) does. One to 24 hours after the application, wing buds were fixed, sectioned, and prepared for autoradiography. Heavy labeling was observed in the peripheral region of the wing mesoderm, but no gradient along the antero-posterior axis was found.
These results suggest that the peripheral region of the limb bud may be important for the morphogenetic function of RA. Tissue-bound retinoids may not form an antero-posterior concentration gradient when retinoids are added to the anterior margin of the chick limb bud.     

The recombinant limb as a model for the study of limb patterning, and its application to muscle development

The recombinant limb is a model system that has proved fruitful for analyzing epithelial-mesenchymal interactions and understanding the functional properties of the components of the limb bud. Here we present an overview of some of the insights obtained through the use of this technique. Among these are the understanding that fore or hind limb identity is inherent to the limb bud mesoderm, that the apical ectodermal ridge (AER) is a permissive signaling center and that the limb bud ectoderm plays a central role in the control of dorsoventral polarity. Recombinant limb studies have also allowed the identification of the affected tissue component in several limb mutants. More recently this model has been applied to the study of regulation of gene expressions related to patterning. In this report we use recombinant limbs to analyze pattering of the Pax3 expressing limb muscle cell lineage in the early stages of limb development. In recombinant limbs made without the zone of polarizing activity (ZPA), myoblasts appear intermingled with other mesodermal cells at the beginning of the recombinant limb development. Rapidly thereafter, the muscle precursors segregate and organize around the central forming chondrogenic core of the recombinant. Although this segregation is reminiscent of that occurring during normal development, the myoblasts in the recombinant fail to proliferate appropriately and also fail to migrate distally. Consequently, the muscle pattern in the recombinant limb is defective indicating that normal patterning cues are absent. However, recombinant limbs polarized with a ZPA exhibited a larger mass of muscle cells and a more normal morphogenesis, supporting a role for this signaling center in limb muscle development. Finally, we have ruled out host somite contributions to recombinant limbs by grafting chick recombinant limbs to quail hosts. This initial report demonstrates the value of the recombinant limb model system for dissecting the environmental cues required for normal muscle limb patterning. Received: 31 August 1998 / Accepted: 29 September 1998     

Cell Sorting and Chondrogenic Aggregate Formation in Limb Bud Recombinants and in Culture

The cartilage pattern of the developing chick limb changes along the proximal-distal (PD) axis. It is assumed that these spatial changes are brought about by differences in the cellular properties of distal mesoderm, the progress zone (PZ). To examine whether these differences are actually maintained in the individual cells composing the PZ, we dissociated early (stage 20) and late (stage 25) PZ tissues into single cells, then mixed and recombined them with ectodermal jackets. The recombinants were grafted to limb bud stumps and allowed to develop into limb-like structures. Early PZ cells were distributed within whole cartilage elements along the PD axis of the limb-like structures, while cells from late PZ participated only in the formation of distal cartilage elements.
A difference in distribution pattern between the cells of early and late PZ in mixed culture was also observed. Cells of early PZ aggregated rapidly in patches and formed cartilage nodules, while the cells of late PZ distributed in regions surrounding these cell aggregates and gradually differentiated to cartilage cells. These results suggest that the cellular properties in the PZ concerning the rate of chondrogenic aggregate formation change during limb bud development, and that this change may relate to the cartilage pattern formation along the PD axis.