Preservation of the ability of dissociated quail wing bud mesoderm to elicit a position-related differentiative response

Previous studies showed that grafting wedges of fresh or cultured anterior quail wing mesoderm into posterior slits in chick wing buds resulted in the formation of supernumerary cartilage in a high percentage of cases. When anterior quail mesoderm, which had been dissociated into single cells and pelleted by centrifugation, was grafted into posterior slits of host chick wing buds, supernumerary rods or nodules of cartilage formed in 74.3% of the cases. Few supernumerary skeletal structures formed following control operations in which pelleted dissociated anterior or posterior mesoderm was grafted into homologous locations in host chick wing buds. When pelleted, dissociated anterior mesoderm was cultured in vitro for 1 or 2 days prior to being implanted in posterior locations, the incidence of supernumerary cartilage formation increased to 95.5% and 93.8%, respectively. The incidence of supernumerary cartilage formation following control orthotopic grafts of cultured mesoderm was 11.8% for 1-day and 31% for 2-day cultured anterior mesoderm; for 1- and 2-day cultured posterior mesoderm, the incidence of supernumerary cartilage formation was 20% and 41.7%, respectively. Longer-term culture resulted in a substantial decrease in the percentage of supernumerary cartilage after anterior to posterior grafts and an increase in the incidence of supernumerary cartilage from control grafts. The results demonstrate that quail anterior wing bud mesodermal cells do not need to maintain constant contact with one another in order to retain the ability to form or stimulate the formation of supernumerary cartilage after being grafted into a posterior location in a host wing bud. This ability is retained when the pelleted dissociated mesoderm is cultured in vitro outside the limb field for at least 1 to 2 days.     

Supernumerary limb structures after juxtaposing dorsal and ventral chick wing bud cells

The formation of duplicated wing skeletal elements and/or extra wing muscles was studied by juxtaposing normally nonadjacent embryonic chick wing bud cells. A wedge of right or left stage 21 wing bud ectoderm and mesoderm was inserted in a slit made in a host stage 20 to 22 right wing bud at the same anteroposterior position as its position of origin. The distal edge of the donor wedge and host wing bud were aligned with each other. Donor tissue was grafted into a host wing bud in one of the following four axial relationships: both the anteroposterior and dorsoventral axes corresponded with each other (aadd); only the anteroposterior axes were opposed (apdd); only the dorsoventral axes were opposed (aadv); both the anteroposterior and dorsoventral axes were opposed (apdv). Of the 63 wings resulting from the control aadd operation and the 45 wings from the apdd operation, only 12 wings had a duplicated skeletal element; of the 69 wings sectioned from these two groups of operations, only one had an extra muscle. However, of the wings resulting from the aadv and apdv operations (48 and 52 cases, respectively), 23 had a duplicated skeletal element; of the 54 wings sectioned from these operations, 43 wings had one to four extra muscles. Furthermore, when the aadv operation was performed with a wedge of donor quail wing bud ectoderm and mesoderm or mesoderm alone, supernumerary muscles formed in these chimeric wings and they were made up of donor quail and host chick cells or only donor quail cells.     

The preservation of the ability of cultured quail wing bud mesoderm to elicit a position-related differentiative response

A previous study showed that grafting wedges of fresh anterior quail wing mesoderm into posterior slits of chick wing buds resulted in the formation of rods and nodules of cartilage in a high percentage of cases (B. Carlson, 1983, Dev. Biol. 101, 97-105). The purpose of the present study was to determine if a similar response could be elicited by grafting pieces of mesoderm that had been cultured in vitro. When pieces of 1-day cultured anterior mesoderm from stage 17-24 donors were grafted into standard posterior slits of chick wing buds, the percentages of supernumerary structures differed little from those which formed after the grafting of pieces of fresh mesoderm. In a time series, grafts of stage 22-23 anterior mesoderm which had been cultured for 1-4 days retained the ability to form cartilage after being grafted into posterior locations. A time series showed that the duration of this retention was longer in cultured mesoderm than it was in mesoderm that remains in the donor wing bud.     

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.     

Posterior apical ectodermal ridge removal in the chick wing bud triggers a series of events resulting in defective anterior pattern formation

The ability of the anterior apical ectodermal ridge to promote outgrowth in the chick wing bud when disconnected from posterior apical ridge was examined by rotating the posterior portion of the stage-19/20 to stage-21 wing bud around its anteroposterior axis. This permitted contact between the anterior and posterior mesoderm, without removing wing bud tissue. In a small but significant number of cases (10/54), anterior structures (digit 2) formed spatially isolated from posterior structures (digits 3 and 4). Thus, continuity with posterior ridge is not a prerequisite for anterior-ridge function in the wing bud. Nevertheless, posterior-ridge removal does result in anterior limb truncation. To investigate events leading to anterior truncation, we examined cell death patterns in the wing bud following posterior-ridge removal. We observed an abnormal area of necrosis along the posterior border of the wing bud at 6-12 h following posterior-ridge removal. This was followed by necrosis in the distal, anterior mesoderm at 48 h postoperatively and subsequent anterior truncation. Clearly, healthy posterior limb bud mesoderm is needed for anterior limb bud survival and development. We propose that anterior truncation is the direct result of anterior mesodermal cell death and that this may not be related to positional specification of anterior cells. In our view, cell death of anterior mesoderm, after posterior mesoderm removal, should not be used as evidence for a role in position specification by the polarizing zone during the limb bud stages of development. We suggest that the posterior mesoderm that maintains the anterior mesoderm need not be restricted to the mapped polarizing zone, but is more extensively distributed in the limb bud.     

The formation of supernumerary structures after grafting anterior quail wing bud mesoderm of various ages into chick wing buds

Wedges of anterior quail mesoderm grafted into posterior slits in the wing buds of chick embryo hosts result in the formation of rods and nodules of supernumerary cartilage in a high percentage of cases. Identifiable digits do not form unless the ectoderm is allowed to remain on the grafts. Control experiments have shown that wedges of anterior or posterior wing mesoderm placed into homologous locations of host wing buds produce few or no supernumerary skeletal structures. Anterior-to-posterior grafts of stage 17 mesoderm evoke a 71.4% incidence of supernumerary cartilage. This percentage increases to 100% with stage 22 donor mesoderm. The percentage of supernumerary structures formed declines markedly with donor mesoderm of stages 24-30. By stages 35-36, only 10% of the grafts result in the formation of supernumerary structures. The period of decline coincides with the onset of overt cytodifferentiation within the donor mesoderm.     

Developmental changes of the hand skeleton induced by grafting leg mesoderm to the wing bud in the chicken

Summary In chick embryos of the stages 20 to 24, a fairly large portion of the intermediary region of the hind-limb was introduced into the wing bud from which a corresponding block of tissues had been excised. The graft was inserted with its axes coincident with those of the host bud, and it came in contact distally with a layer of apical mesoderm subjacent to the apical ridge leftin situ in the wing bud. According to the maps of the prospective territories, the graft contained part of the mesodermal territories of the stylo-zeugopod of the hind-limb; the layer of apical mesoderm leftin situ in the wing bud, distal to the graft, would have given origin to the hand.The grafted mesoderm showed a tendency to a gradual developmental reduction; apparently, it did not take a detectable part in the organogenesis of the host autopod. An anomalous cartilaginous nodule proximal to the wrist differentiated from the distal remnants of the graft; the rest of the graft took part possibly in the formation of the arm and forearm skeleton, which appeared normal or slightly reduced.The hand of the host wing showed a variety of quantitative and/or qualitative differences in the anatomy of its skeleton in comparison to the normal hand of the intact contralateral wing. These differences involved the part of the hand which apparently developed from the apical mesoderm of the host which lay distal to the graft. Cartilaginous pieces of normal shape but bigger than the controls, or variously modified as to their shape were observed consistently. In a significant percentage of embryos, the third ray of the hand showed morphological features more typical of a toe than of a hand-digit, or a supernumerary toe developed in association with the hand digits which appeared reduced to various degrees.The results are tentatively interpreted as the consequence of changes of the normal prospective pattern of development of the apical mesoderm of the host wing bud induced by the grafted mesoderm of the hind-limb. It is suggested that the mesoderm of the graft produced molecular materials which propagated to the overlying undifferentiated apical mesoderm of the host wing, and exerted inductor influences on the growth and on the further steps of development of the latter.

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Zusammenfassung In Hühnerembryonen der 20–24 Stadien wurde ein ziemlich breiter Teil der Zwischengegend der Flügelanlage durch den entsprechenden Teil der Beckengliedanlage ersetzt. Der dem Beckenglied entnommene Block wurde so eingesetzt, daß seine Achsen mit jenen der Empfängeranlage zusammenfielen und daß er distal mit einer auf dem Flügelin situ gelassenen Schicht von apikalem Mesoderm in Berührung kam. Gemäß dem Plan der mutmaßlichen Gegenden enthielt das Transplantat einen Teil des Stylopod- und Zygopodmesoderma des Beckengliedes, während die auf der Flügelanlage distal vom Transplantatin situ gelassene Mesodermschicht dazu bestimmt war, der Hand den Ursprung zu geben.Die Entwicklung des verpflanzten Mesoderms unterging einer graduellen Reduktion und wirkte nicht in abschätzbarer Weise an der Organogenese der Empfängerhand mit. Ein dem Handgelenk proximal gelegenes Knorpelknötchen differenzierte sich auf Kosten des distalen Teiles das Transplantats; das restliche Transplantat wirkte wahrscheinlich an der Entwicklung des Armes und des Vorderarmes mit, welche jedoch normal oder leicht verkleinert erschienen.Die Anatomie des Handknochengerüstes des Empfängerflügels wies eine Mannigfaltigkeit von quantitativen und/oder qualitativen Differenzen gegenüber der normalen Hand des nicht operierten kontralateralen Flügels auf. Diese Differenzen betrafen nur jenen Mesodermteil des Empfängers, welcher distal vom Transplantat gelegen war. Beständig entwickelten sich. Knorpelsegmente normaler Form, welche aber größer als jene der Kontrollen oder verschiedentlich in ihrer Form abgeändert waren. In einem signifikativen Prozentsatz von Embryonen waren die morphologischen Merkmale des dritten Fingers der Hand mehr jenen einer Zehe ähnlich als eines Flügelfingers; in verschiedenen Fällen entwickelte sich eine überzählige Zehe in Verbindung mit verschiedentlich verkleinerten Fingern.Diese Ergebnisse können als eine Folge der Abänderungen des normalen Entwicklungsplanes des distalen Mesoderms der Empfängerflügelanlage gedeutet werden: Abänderungen, welche vom Mesoderm des verpflanzten Beckengliedes verursacht wurden. Es kann vermutet werden, daß das Transplantatmesoderm Molekularstoffe erzeugt, welche sich durch Berührung auf das indifferenzierte darübergelegene Mesoderm der Empfängeranlagenspitze verbreiten und Induktionswirkung auf das Wachstum und die weiteren Entwicklungsetappen ausüben.

     

The in vitro maintenance of the apical ectodermal ridge of the chick embryo wing bud: an assay for polarizing activity.

We have devised an in vitro bioassay for limb bud polarizing activity in the chick embryo. This assay has proven to be a relatively quick and effective test for a morphogenetic factor asymmetrically distributed in the limb bud which is capable of maintaining or thickening the apical ectodermal ridge.A small section of the preaxial border of the chick embryo wing bud was cultured alone, with tissue from the posterior border, mid-dorsal or anterior corner of a second donor wing, or from the flank. The tissue from the preaxial border (responding tissue) consisted of mesoderm with overlying ectoderm and apical ectodermal ridge. When the responding tissue was cultured alone, with flank, or with anterior corner limb tissue, the apical ectodermal ridge flattened in 24–36 hr and many macrophages appeared in the underlying mesoderm. When cultured with posterior border limb tissue however, the apical ridge of the responding tissue remained thickened for up to 48 hr., and no macrophages appear in the underlying mesoderm. The behavior of responding tissue was intermediate between these two extremes when cultured with mid-dorsal limb tissue. The morphogenetic activity assayed by this procedure thus seems to be present as a gradient in the wing bud, with activity decreasing from posterior to anterior. Contact with the responding tissue is not required to enable posterior border tissue to elicit ridge thickening and inhibit the cell death.     

A comparative study of myogenic cell invasion of the avian wing and leg bud.

The borders of myogenic cell invasion of avian wing and leg buds were determined using the interspecific grafting technique between quail and chick embryos. Distal parts of quail limb buds were grafted ectopically into the coelomic cavity of chick embryos. The presence or absence of skeletal muscle was investigated in histological sections of the reincubated grafts. A comparison between the borders of myogenic cell invasion of the wing and leg buds showed that the differences in the position of the distal most muscles in the adult avian limbs could be a consequence of the cranio-caudal sequence of development.     

Spatial and temporal patterns of cell death in limb bud mesoderm after apical ectodermal ridge removal

A spatiotemporal pattern of cell death occurred in the chick wing and leg bud mesoderm after removal of apical ectodermal ridge at stages 18–20. Cells died in a region extending from the limb bud distal surface to 150–200 μm into the mesoderm. Limb buds from which ridge was removed at later stages in development did not exhibit a spatiotemporal pattern of cell death. In control experiments in which dorsal ectoderm was removed, a pattern of cell death did not occur. Removal of the ridge and part of the 150- to 200-μm zone of prospective cell death resulted in cell death in an area approximately equal to the amount of the zone remaining. After removal of all of the prospective zone of cell death plus the apical ridge, cell death was observed in the remaining limb bud mesoderm. In these limb buds, cell death occurred in a region in which it had not been seen in limb bud with apical ridge alone removed. We conclude that at stages 18–20 the mesodermal cells 150–200 μm beneath the ridge require the apical ridge to survive. More proximal mesodermal cells do not die after ridge removal alone, but apparently require the presence of the more distal mesoderm to survive. Whether this is a requirement for something intrinsic to the distal mesoderm or something it possesses by way of the ridge is unknown. After stage 23, the limb mesoderm cells do not die when the apical ridge is removed. Nevertheless, at the later stages, ridge continues to be required for limb bud proximal-distal elongation and the differentiation of distal limb elements.     

A test of positional properties of avian wing-bud mesoderm

Supernumerary wing structures are readily produced by grafting pieces of wing-bud mesoderm into different locations of host wing buds, but the mechanism underlying their formation remains obscure. The major aim of this study was to examine the ability of posterior quail wing-bud mesoderm, cultured in vitro long enough to lose ZPA (zone of polarizing activity) activity, to stimulate or participate in the formation of supernumerary structures when grafted into anterior slits of host chick wing buds. Small pieces of anterior and posterior quail wing-bud mesoderm (HH stages 21-23) were placed in in vitro culture for up to 3 days. After 2 days, ZPA activity of cultured mesoderm was lost. After the grafting of 2- to 3-day cultured anterior quail wing-bud mesoderm into posterior slits of host chick wing-buds, a consistently high percentage (70%-90%) of grafts result in formation of supernumerary cartilage; in this experiment, however, only a low percentage of grafts resulted in supernumerary cartilage when 2- to 3-day cultured posterior mesoderm was grafted into anterior slits. Taken with controls, these results show that positional differences exist between cultured anterior and posterior wing-bud mesoderm. Serial-section analysis of numerous operated wings has shown several patterns of contribution to supernumerary structures by cells of graft and host. Single supernumerary digits induced by grafts of ZPA mesoderm into anterior slits were normally composed entirely of host cells, but graft cells regularly contributed to skeletal elements of more complex supernumerary structures. Cartilage rods produced by anterior-to-posterior grafts were composed mostly of graft cells, but cartilage nodules and the bases of some rods were often mosaics of chick and quail cells. The results support the proposition that mesodermal cells of the quail wing-bud possess a form of anteroposterior positional memory, but its nature and the means by which the memory of grafted cells interacts with host mesoderm are still not clear.     

Experimental manipulation leading to induction of dorsal ectodermal ridges on normal limb buds results in a phenocopy of the eudiplopodia chick mutant

Elongation of chick limb buds depends on the presence of the apical ectodermal ridge which is induced by subjacent limb bud mesoderm. Recombination experiments have shown that the limb bud mesoderm loses the capacity to induce ridges by late stage 17. Moreover, in normal limb development only one ridge forms. However, in the eudiplopodia chick mutant accessory ectodermal ridges form on the dorsal surface of limb buds as late as stage 22. Tissue recombinant experiments show that the mutation affects the ectoderm, extending the time it responds to ridge induction (Fraser and Abbott, 1971a, Fraser and Abbott, 1971b while the mesoderm is normal. The result is polydactyly, with extra digits dorsal to the normal digits. Because eudiplopodia limb bud dorsal mesoderm can induce ridges at stage 22 but is unaffected by the gene, genetically normal dorsal limb bud mesoderm may also be able to induce ridges after stage 17. To test this possibility we grafted stages 14–18 flank ectoderm to normal limb bud dorsal mesoderm and found that mesoderm from stages 17 through 20 was able to induce a ridge and subsequently dorsal digits developed. Limbs with duplicate digits were similar to eudiplopodia limbs. In other experiments, stage 18, 19, and 20 leg bud dorsal ectoderm did not form ridges when grafted to leg bud dorsal mesoderm of the same stage, indicating a lack of response to the mesoderm. Finally, the inductive capacity of limb bud mesoderm appeared to be reduced compared to mesoderm at pre-limb bud stages. These experiments demonstrate a spatially generalized potential in limb bud dorsal mesoderm to induce ridges during the stages when the apical ridge is induced. The determination of where the ridge will form and the acquired inability of limb bud dorsal ectoderm to respond to induction by underlying mesoderm are necessary early pattern forming events which assure that a single proximodistal limb axis will form.     

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.     

Initial limb budding is independent of apical ectodermal ridge activity; evidence from a limbless mutant

Outgrowth of normal chick limb bud mesoderm is dependent on the presence of a specialized epithelium called the apical ectodermal ridge. This ectodermal ridge is induced by the mesoderm at about the time of limb bud formation. The limbless mutation in the chick affects apical ectodermal ridge formation in the limb buds of homozygotes. The initial formation of the limb bud appears to be unaffected by the mutation but no ridge develops and further outgrowth, which is normally dependent on the ridge, does not take place. As a result, limbless chicks develop without limbs. In the present study, which utilized a pre-limb-bud recombinant technique, limbless mesoderm induced an apical ectodermal ridge in grafted normal flank ectoderm. However, at stages when normal flank ectoderm is capable of responding to ridge induction, limbless flank ectoderm did not form a ridge or promote outgrowth of a limb in response to normal presumptive wing bud mesoderm. We conclude from this that the limbless mutation affects the ability of the ectoderm to form a ridge. In addition, because the limbless ectoderm has no morphological ridge and no apparent ridge activity (i.e. it does not stabilize limb elements in stage-18 limb bud mesoderm), the limbless mutant demonstrates that the initial formation of the limb bud is independent of apical ectodermal ridge activity.     

Inhibitory effect on limb morphogenesis by cells of the polarizing zone coaggregated with pre- or postaxial wing bud mesoderm.

The influence of cells of the polarizing zone mesoderm on the morphogenesis of recombinant chick limbs was studied. The recombinant buds were composed of leg bud ectoderm and different regions of the wing bud mesoderm, which had been dissociated and reaggregated. In any case where the polarizing zone mesoderm was coaggregated with the wing mesoderm the morphogenetic capabilities of the recombinant were reduced. This was the case with postaxial mesoderm, preaxial mesoderm plus polarizing tissue, and postaxial mesoderm from which a piece of the nonpolarizing mesoderm (comparable in size to the polarizing zone) had been removed. All of these gave outgrowths with digits in only a very low percentage of cases. In contrast, those recombinants without polarizing mesoderm developed outgrowths with digits in a high percentage of cases, indicating good morphogenesis. Finally, if the polarizing zone were removed prior to dissociation, the recombinant limb, composed of the total remaining wing bud mesoderm plus leg bud ectoderm, exhibited a higher percentage of complete morphogenesis than if the polarizing zone had been part of the recombinant.It is clear that cells of the polarizing zone, when dissociated, and coaggregated with wing mesoderm, are inhibitory to the morphogenetic performance of that mesoderm in the recombinant limb situation.     

The ability of the chick wing bud to regulate positional disparity along the anterior-posterior axis

When wedges of wing bud tissue are added to a host wing bud so there is positional disparity between graft and host, skeletal duplications result (L. E. Iten and D. J. Murphy 1980) Dev Biol. 75, 373-385. The polarity of the duplications is predictable by the polar coordinate model, leading to the interpretation that the positional disparity caused the duplications. To determine whether positional disparity alone causes duplications, without the complication of added tissue, we rotated wedges of ectoderm and mesoderm around the proximodistal axis within the wing bud. Wedges measuring 200-800 micron along the distal edge were rotated 180 degrees at stages 20-22, reversing the anteroposterior and dorsoventral axes relative to the bud. This caused positional disparity, similar to that achieved by Iten and Murphy (1980), without the addition of tissue. We found that rotations involving no polarizing zone tissue produced normal wings or wings lacking some distal parts, as did rotations of tissue lying entirely within the polarizing zone. However, when polarizing zone mesoderm was displaced, so that polarizing and nonpolarizing tissues were juxtaposed, a majority of the operations produced polarized skeletal duplications. Our data demonstrate that positional disparity alone does not cause skeletal duplications in the chick wing bud, unless polarizing zone tissue is displaced. Further, these data demonstrate that the chick wing bud can regulate to form a normal wing skeleton in the face of large positional disparity, provided that the polarizing zone is not moved. Finally, our results may be explained by the action of the proposed polarizing morphogen on the displaced cells causing repolarization.     

Limb outgrowth in the chick embryo induced by dissociated and reaggregated cells of the apical ectodermal ridge.

Mesodermal cores of the stage 19 chick leg bud were capped with an intact apical ectodermal ridge (AER) or with strips cut from centrifugal pellets formed from Pronase-dissociated AERs. They were then covered with embryonic back-skin ectoderm and grown as grafts to the somite region of a host embryo. Control mesoderms were capped with centrifugal aggregates of nonridge limb ectoderm or similarly treated back-skin ectoderm, with ethanol-killed AERs or with no ectodermal cells other than the enveloping back-skin ectoderm.Controls were vascularized slowly and atypically and showed little outgrowth, forming only proximal skeletal structures. Recombinants equipped with AER cells were vascularized more fully and promptly and began vigorous growth after brief delay, forming legs with all skeletal segments represented, including claw-tipped toes. The latter were arranged in anteroposterior order corresponding to the original polarity of the mesoderm.Histological sections of recombinants made with cytologically distinctive quail AERs reveal that the cap of ridge cells, whether initially intact or reaggregated beneath the back-skin envelope, undergo a period of reorganization, forming a typical AER at the apex of the chimeric appendage after 48 hr. Meanwhile vigorous growth of the recombinant continues.These results show that the AER can cooperate with nonlimb ectoderm in promoting the morphogenesis of successively more distal levels of the limb skeleton. They also show that dissociated ridge cells can reorganize a typical AER at the apex of the limb mesoblast, meanwhile exercising their inductive effect on it.     

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

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.     

Formation of supernumerary structures by the embryonic chick wing depends on the position and orientation of a graft in a host limb bud

The relationship between the position transplanted in a host limb bud, the orientation of a graft in a host limb bud, and the extra limb structures formed was studied by juxtaposing normally nonadjacent embryonic chick wing bud tissue. In one series of transplantation operations, two different wedges (ectoderm and mesoderm) of stage 21 right donor posterior wing bud tissue were transplanted to the middle of a host stage 20 to 22 right wing bud such that the dorsal-ventral polarity of the graft and host were the same or reversed. The results of these transplantation operations show that the formation of supernumerary limb structures depends on the position of origin of the donor tissue, the anterior-posterior position transplanted in a host limb bud, and the orientation of the graft in the host limb bud. In a second series of transplantation operations, the relationship between the proximodistal position where posterior donor tissue is transplanted in an anterior host site and the extra structures formed was studied. A wedge of posterior stage 21 right wing bud tissue was transplanted to an anterior proximal or anterior distal site of a stage 22 to 24 host right wing bud. The results of these transplantation operations show that when the donor tissue is transplanted to an anterior proximal position in a host wing bud, then limbs with only a duplicated humerus result, whereas, when transplanted to an anterior distal position, then limbs with a duplicated forearm element and extra digits result.     

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)