Characterization of retinoid metabolism in the developing chick limb bud

Retinoids (vitamin A derivatives) have been shown to have striking effects on developing and regenerating vertebrate limbs. In the developing chick limb, retinoic acid is a candidate morphogen that may coordinate the pattern of cellular differentiation along the anteroposterior limb axis. We describe a series of investigations of the metabolic pathway of retinoids in the chick limb bud system. To study retinoid metabolism in the bud, all-trans-[3H]retinol, all-trans-[3H]retinal and all-trans-[3H]retinoic acid were released into the posterior region of the limb anlage, the area that contains the zone of polarizing activity, a tissue possibly involved in limb pattern formation. We found that the locally applied [3H]retinol is primarily converted to [3H]retinal, [3H]retinoic acid and a yet unidentified metabolite. When [3H]retinal is locally applied, it is either oxidized to [3H]retinoic acid or reduced to [3H]retinol. In contrast, local delivery of retinoic acid to the bud yields neither retinal nor retinol nor the unknown metabolite. This flow of metabolites agrees with the biochemical pathway of retinoids that has previously been elucidated in a number of other animal systems. To find out whether metabolism takes place directly in the treated limb bud, we have compared the amount of [3H]retinoid present in each of the four limb anlagen following local treatment of the right wing bud. The data suggest that retinoid metabolism takes place mostly in the treated limb bud. This local metabolism could provide a simple mechanism to generate in a controlled fashion the biologically active all-trans-retinoic acid from its abundant biosynthetic precursor retinol. In addition, local metabolism supports the hypothesis that retinoids are local chemical mediators involved in pattern formation.     

Abnormal anteroposterior and dorsoventral patterning of the limb bud in the absence of retinoids.

We describe here how the early limb bud of the quail embryo develops in the absence of retinoids, including retinoic acid. Retinoid-deficient embryos develop to about stage 20/21, thus allowing patterns of early gene activity in the limb bud to be readily examined. Genes representing different aspects of limb polarity were analysed. Concerning the anteroposterior axis, Hoxb-8 was up-regulated and its border was shifted anteriorly whereas shh and the mesodermal expression of bmp-2 were down-regulated in the absence of retinoids. Concerning the apical ectodermal genes, fgf-4 was down-regulated whereas fgf-8 and the ectodermal domain of bmp-2 were unaffected. Genes involved in dorsoventral polarity were all disrupted. Wnt-7a, normally confined to the dorsal ectoderm, was ectopically expressed in the ventral ectoderm and the corresponding dorsal mesodermal gene Lmx-1 spread into the ventral mesoderm. En-1 was partially or completely absent from the ventral ectoderm. These dorsoventral patterns of expression resemble those seen in En-1 knockout mouse limb buds. Overall, the patterns of gene expression are also similar to the Japanese limbless mutant. These experiments demonstrate that the retinoid-deficient embryo is a valuable tool for dissecting pathways of gene activity in the limb bud and reveal for the first time a role for retinoic acid in the organisation of the dorsoventral axis.     

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.     

The respecification of limb pattern by new synthetic retinoids and their interaction with cellular retinoic acid-binding protein

We describe here experiments to examine the role of cellular retinoic-acid-binding protein (CRABP) during the induction of limb duplication in the chick limb bud and regenerating axolotl limb by retinoids. A newly synthesised class of retinoic acid analogues have been used because among them, some have been specifically designed with the property of binding to the retinoic acid receptors, but not to CRABP. We can thus test whether binding to CRABP is an obligatory step during limb respecification. The binding of four of these compounds to chick limb bud and axolotl CRABP was tested in sucrose density gradient assays and then their potencies at inducing limb duplications tested. Two of the four compounds do not bind to limb CRABP and yet are able to induce limb duplications, suggesting that an interaction with CRABP is not an obligatory step in the process. However, the two compounds which do bind to CRABP are more potent than the two which do not, suggesting that an interaction with CRABP may, nevertheless, increase the potency of a retinoid.     

Identification of the cellular retinoic acid binding protein (cRABP) within the embryonic mouse (CD-1) limb bud

Retinoic acid, a physiologically active metabolite of vitamin A, is known animal teratogen. Among other malformations, limb abnormalities are produced and are attributed to a selective inhibition of differentiating prechondrogenic mesenchyme resulting in reduced or absent cartilage elements. Evidence is available that the cellular retinoic acid binding protein (cRABP) may be important in mediating the biological effects of retinoic acid. In this study, the cRABP has been identified by sucrose gradient sedimentation analysis in the gestation day 10 (Theiler stages 16-17) mouse forelimb bud, which contains retinoic-acid-sensitive prechondrogenic mesenchyme. Saturation analysis demonstrated values for the apparent dissociation constant (Kd) of 2.0 and 2.2 X 10(-9)M and for the total specific binding capacity for [3H]-trans-retinoic acid of 24.5 and 25.6 pmoles per mg cytosolic protein. The binding specificity of the forelimb bud cRABP for all-trans-retinoic acid was demonstrated in competition assays using all-trans-retinol, all-trans-retinal, and 13-cis-retinoic acid. In addition, 13-cis-retinoic acid was demonstrated to have a lower affinity for the cRABP than all-trans-retinoic acid, a result which may be related to the lower teratogenic potency of the 13-cis-retinoic acid. Thus, the cRABP was demonstrated in the mouse forelimb bud at a time of susceptibility for the production of limb malformations by retinoic acid. The role of the cRABP in the mechanism of retinoic acid teratogenicity remains to be delineated.     

Effects of retinoic acid treatment on release of arachidonic acid by chondrogenic cells in response to ionophore A23187

Chondrogenic differentiation in mouse limb bud mesenchymal cells cultured at high density was suppressed by supplementation of the medium with retinoic acid in a dose-dependent fashion. Cells prelabeled with (3H) arachidonic acid were treated with 0.3 microgram/ml retinoic acid. Treatment with retinoic acid increased the (3H) fatty acid in the triglyceride fraction. Furthermore, treatment with retinoic acid enhanced the release of (3H) fatty acid upon stimulation of these cells with the divalent ionophore A23187. These data permit the suggestion that there may be a correlation between altered lipid metabolism and retinoic acid's ability to disrupt chondrogenic differentiation.     

Effects of vitamin D metabolites on axolotl limb regeneration

Vitamin D is essential for normal metabolism of phosphorus and calcium, and differentiation of skeletal elements. 1,25 dihydroxyvitamin-D₃, the biologically active metabolite, acts as an induction/proliferation switch in various cell types and promotes chondrogenesis of chick limb bud mesenchymal cells. The function of vitamin D is mediated through its nuclear receptor, the vitamin D receptor (VDR). The proliferative actions of 1,25(OH)₂-D₃ on limb bud mesenchymal cells are similar to the ones produced by retinoids, such as all- trans retinoic acid (RA) or 9- cis retinoic acid (9- cis ). The retinoids have been shown to be compounds of extreme importance in the field of limb development and regeneration. In order to examine possible roles of vitamin D metabolites on limb regeneration, the effects of 1,25(OH)₂-D₃, 24,25(OH)₂-D₃ and KH1060 (a more potent metabolite) alone or in conjunction with all- trans RA or 9- cis RA on the regenerating axolotl limb. Vitamin D affects limb morphogenesis by generating abnormalities in skeletal elements. Synergism of vitamin D with retinoic acid in affecting pattern formation is suggested by the results.     

Studies on the mechanism of retinoid-induced pattern duplications in the early chick limb bud: temporal and spatial aspects

All-trans-retinoic acid causes striking digit pattern changes when it is continuously released from a bead implanted in the anterior margin of an early chick wing bud. In addition to the normal set of digits (234), extra digits form in a mirror-symmetrical arrangement, creating digit patterns such as a 432234. These retinoic acid-induced pattern duplications closely mimic those found after grafts of polarizing region cells to the same positions with regard to dose-response, timing, and positional effects. To elucidate the mechanism by which retinoic acid induces these pattern duplications, we have studied the temporal and spatial distribution of all-trans-retinoic acid and its potent analogue TTNPB in these limb buds. We find that the induction process is biphasic: there is an 8-h lag phase followed by a 6-h duplication phase, during which additional digits are irreversibly specified in the sequence digit 2, digit 3, digit 4. On average, formation of each digit seems to require between 1 and 2 h. The tissue concentrations, metabolic pattern, and spatial distribution of all- trans-retinoic acid and TTNPB in the limb rapidly reach a steady state, in which the continuous release of the retinoid is balanced by loss from metabolism and blood circulation. Pulse-chase experiments reveal that the half-time of clearance from the bud is 20 min for all-trans- retinoic acid and 80 min for TTNPB. Manipulations that change the experimentally induced steep concentration gradient of TTNPB suggest that a graded distribution of retinoid concentrations across the limb is required during the duplication phase to induce changes in the digit pattern. The extensive similarities between results obtained with retinoids and with polarizing region grafts raise the possibility that retinoic acid serves as a natural "morphogen" in the limb.     

Inhibition and reversion of chondrogenesis by retinoic acid in rat limb bud cell cultures

Summary Mesenchyme cells derived from embryonic rat limb buds cultured at high density differentiated into chondrocytes. The degree of chondrogenesis was assessed by alcian blue staining, a stain specific for cartilage matrix. The addition of retinoic acid on day 1 of culture inhibited chondrogenesis in a dose-dependent fashion. When retinoic acid was added to the cultures on day 5, the cartilage nodules, consisting of newly differentiated cartilage cells, disappeared during the following 6 days. Coinciding with this process the histochemically demonstrable alkaline phosphatase activity, localized in the internodular areas, also disappeared. This indicated that retinoic acid not only inhibited chondrogenesis but also induced resorption of cartilage cells and that at least two cell types were affected, the cartilage cells and the cells bearing alkaline phosphatase.Actinomycin D and cycloheximide, inhibitors of RNA and protein synthesis, suppressed the retinoic acid effect in day 5 limb bud cell cultures. This result indicated that the effect of retinoic acid required RNA and protein synthesis and is compatible with the view that vitamin A may act in a hormone-like way.     

A quantitative analysis of the effect of all-trans-retinoic acid on the pattern of chick wing development

Small, positively charged beads that slowly release known amounts of all-trans-retinoic acid have been implanted below the apical ectodermal ridge at the anterior margin (opposite somite 16) of wing buds of 3 1/2 day-old chick embryos. The continuous release of retinoic acid is shown to create an anteroposterior concentration gradient of retinoic acid in the limb field that is stable with time, despite the fact that this compound is metabolized by the limb tissue. With beads that release increasing amounts of retinoic acid, the normal 234 digit pattern is progressively altered to a 2234, to a 32234, and then to a 432234 pattern. The tissue concentrations of all-trans-retinoic acid required to change the digit pattern in this way range between 1 and 25 nM. When the same amounts of retinoic acid are released from posteriorly implanted beads (placed below the apical ectodermal ridge opposite somite border 19/20 or somite 20), the normal digit pattern is unaffected. Implantations of beads that release all-trans-retinoic acid are thus identical in their effect to grafts of cells from the limb polarizing region, which cause similar dose-dependent changes in the digit pattern when grafted to the anterior margin of the bud (but not when grafted opposite somites 19 or 20). Because of the low concentrations of retinoic acid required for its biological effect, the graded response observed, and the fact that a concentration gradient is established across the limb field, all-trans-retinoic acid closely mimics the putative morphogen that has been postulated to be emitted by polarizing region cells during normal development.     

Retinoic acid and its receptors in limb regeneration

The effects of retinoids on the regenerating amphibian limb are described: the mesenchymal cells of the blastema can be proximalized, posteriorized and ventralized. Ectopic limbs are also induced after retinoid treatment of regenerating tails, but not during limb development unless the limb bud is damaged. The cellular and molecular alterations induced by retinoids are reported as well as experiments which have revealed the importance of endogenous retinoids for normal limb regeneration. Various retinoic acid receptors are expressed in the regeneration blastema and the experiments which have revealed functions for individual isoforms are described. These experiments reveal that retinoids are a crucial component of the normal, regenerating limb and demonstrate the value of the regenerating limb as an experimental system for providing functional data on individual retinoic acid receptors.     

Retinoic acid ambivalently regulates the expression of MyoD1 in the myogenic cells in the limb buds of the early developmental stages.

The expression of MyoD1 in myogenic cells located in the muscle prospective region of the limb bud at stage 20-22 was highly sensitive to retinoic acid. Unlike RAR-beta, the expression of MyoD1 mRNA in the muscle precursor cells was significantly increased by retinoic acid at lower concentrations (0.1-10 nM), but inhibited by it at higher concentrations (0.1-1 microM). The ambivalent modulation of MyoD1 expression suggested that MyoD1 expression is regulated by not only the retinoic acid receptor and its response element, but also by other factors. Retinoic acid may be involved in the differentiation of the myogenic cells during early development.     

Retinoic acid in development and regeneration

Retinoids are low molecular weight, lipophilic derivatives of vitamin A which have profound effects upon the development of various embryonic systems. Here I review the effects on developing and regenerating limbs, regenerating amphibian tails and the developing central nervous system (CNS). In the regenerating amphibian limb, retinoids can proximalize, posteriorize and ventralize the axes of the blastema. In the chick limb bud retinoids can only posteriorize the tissue. In the regenerating amphibian tail retinoids can homeotically transform tail tissue into hindlimb tissue. In the developing and regenerating limb retinoic acid has been detected endogenously, confirming that this molecule plays a role in the generation of pattern and we have shown that limbs cannot develop in the absence of retinoic acid. In the developing CNS retinoic acid specifically affects the hindbrain where it causes a transformation of anterior rhombomeres into more posterior ones. Again, endogenous retinoic acid has been detected in the CNS and in the absence of retinoids the posterior hindbrain has been found to be affected. The effects of retinoids on the CNS are most likely to be mediated via theHox genes acting in the mesoderm after gastrulation. It has also been proposed that the establishment of the head-to-tail axis in the mesoderm is established by retinoic acid. These data show that retinoids play an important role in both the development and regeneration of various systems in the embryo and post-embryonically     

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.     

Identification of a novel isoform of the retinoic acid receptor gamma expressed in the mouse embryo.

Retinoic acid is known to have profound effects on developmental processes. It has been implicated as a putative morphogen in the developing chick limb bud and regenerating amphibian limb blastema and has been demonstrated to have powerful teratogenic effects in mammals, including humans. Recently, three specific retinoic acid receptors (RARs), RAR alpha, -beta, and -gamma, were identified and shown to be members of the steroid receptor superfamily. We report the identification of a novel RAR gamma isoform, mRAR gamma B, which differs from the previously described mouse RAR gamma at its amino terminus. In addition, we show that both RAR gamma isoforms are expressed maximally at midgestation in structures known to be affected adversely by retinoic acid administration to pregnant mice. Multiple RAR isoforms, each of which may play a unique or combinatorial role as a regulator of mammalian development, are thus expressed in the mouse embryo.     

Comparative effects of retinoic acid and jervine on chondrocyte differentiation

Jervine and retinoic acid are both teratogenic to structures which are initially modelled in cartilage. Differences in periods of maximal sensitivity, as well as in certain aspects of the morphological manifestations of exposure, indicate that these two teratogens act via different molecular mechanisms. Here we compare the effects of jervine and retinoic acid in three culture systems which represent sequential stages of the chondrocyte lineage. Proliferation of pluripotent C3H 10T 1/2 cells was decreased by exposure to jervine but was not affected by retinoic acid. Differentiation of high-density "spot" cultures of embryonic limb bud mesenchyme were sensitive to both compounds. Mature chondrocytes were resistant to jervine but "dedifferentiated" after 48-hour exposure to retinoic acid. We conclude that jervine compromises rapidly dividing chondrogenic precursors, whereas retinoic acid has little effect prior to the expression of cartilage-specific proteins.