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

Retinoids and their receptors in skeletal development

The embryonic vertebrate limb serves as an excellent experimental model system in which to study mechanisms that regulate morphogenesis of the skeleton. The appendicular skeleton arises through the process of endochondral ossification, whereby a cartilage template is initially formed and subsequently replaced by bone. One molecule that has a dramatic effect on these processes is the vitamin-A metabolite, retinoic acid (RA). RA functions through a class of nuclear hormone receptors, the retinoic acid receptors (RARs) and retinoid-X-receptors (RXRs), to regulate gene transcription. Experimental evidence from RA teratogenesis suggests that the presence of ligand-activated RARs and/or inappropriate expression of RARs inhibits chondrogenesis. Conversely, genetic analysis has shown that the absence of the receptors can lead to deficiencies in cartilage formation while also promoting chondrogenesis at ectopic sites. Taken together, these studies suggest that the RARs play a fundamental role in the early stages of skeletal development, specifically those involved in the formation of prechondrogenic condensations and their subsequent differentiation into chondroblasts.

Influence of retinol on human chondrocytes in agarose culture

Vitamin A and its congeners, collectively called retinoids, are known to have teratogenic potential and have induced craniofacial and limb malformations in numerous animal species. More importantly, retinoids are recognized as teratogenic to fetuses of pregnant women who have taken such preparations for dermatologic disorders. Information gathered from the study of animal models suggests that retinoids interfere with cartilage differentiation. If chondrogenesis in limb development is disturbed it may contribute to limb reductions and malformations. In vitro studies using various animal systems have shown that cartilage matrix macromolecules are altered to resemble those secreted by mesenchymal cells. The response of human chondrocytes to retinoids in vitro is not known. Culture of human chondrocytes in agarose maintains the cartilage phenotype and therefore serves as a model system to evaluate the influence of retinoids directly on human chondrogenesis. The studies presented in this paper were done to determine if the expression of specific matrix macromolecules of human chondrocytes in agarose culture is altered by retinol treatment. Immunocytochemistry demonstrated enhanced labeling of type I collagen while type II collagen labeling was reduced in cultures treated with retinol. In addition, morphometric analyses indicated a decrease in the size and number of chondrogenic clusters and that individual cells synthesized less alcian blue matrix when compared to parallel control cultures. The size of the proteoglycan monomers, glycosaminoglycan side chains as well as the disaccharide composition were not affected. However, there was a reduction in the quantity of proteoglycan monomers produced.

Differential expression of genes encoding alpha, beta and gamma retinoic acid receptors and CRABP in the developing limbs of the mouse

Retinoic acid has profound effects on vertebrate limb morphogenesis (refs 1-6, reviewed in refs 7-9), including in the mouse, where it can act as a teratogen generating phocomelia and bone defects. A retinoic acid gradient, possibly amplified by a graded distribution of cellular retinoic acid-binding protein (CRABP), could provide positional information across the antero-posterior axis of the chick limb bud. The discovery of nuclear retinoic acid receptors (RARs) acting as retinoic acid-inducible enhancer factors provided a basis for understanding how retinoic acid signals could be transduced at the level of gene expression. We have now used in situ hybridization to study the distribution of messenger RNA transcripts of the three murine receptors (mRARs) and CRABP during mouse limb development. Both mRAR alpha and mRAR gamma transcripts, but not those for mRAR beta, are present and uniformly distributed in the limb bud at day 10 post-coitum, whereas CRABP transcripts have a graded proximo-distal distribution, indicating that differential expression of CRABP, but not of mRAR alpha or mRAR gamma, could participate in the establishment of the morphogenetic field. At later stages, mRAR gamma transcripts become specific to the cartilage cell lineage and to the differentiating skin and mRAR beta transcripts are mostly restricted to the interdigital mesenchyme. CRABP transcripts, however, are excluded from regions expressing mRAR gamma and mRAR beta. These results indicate that all three RARs and CRABP have specific functions during morphogenesis and differentiation of the mouse limb.

Retinoic-acid-induced limb-reduction defects: perturbation of zones of programmed cell death as a pathogenetic mechanism

Pregnant C57Bl/6J mice were treated with 100 mg/kg body weight of all-trans retinoic acid in sesame oil on day 11.0 of gestation. Among the live fetuses harvested on day 18 of gestation, 100% had mesomelic defects of the limbs as determined by gross examination and skeletal staining. Control fetuses treated with sesame oil had no observable limb malformations. Some treated and control embryos were harvested 12 hr after treatment and examined for patterns of cell death by using the supravital stain Nile blue sulphate and methylene-blue- and acid-fuchsin-stained histological sections. Retinoic-acid-induced cell death in the core of the limb was always associated with the zones of programmed cell death as seen in control embryos of comparable stages. This, in concert with previous studies demonstrating excessive cell death in regions of programmed cell death that correlated with subsequent malformations, leads us to conclude that the pathogenesis of mesomelic malformations has a primary association with the phenomenon of programmed cell death.

Elevations in the endogenous levels of the putative morphogen retinoic acid in embryonic mouse limb-buds associated with limb dysmorphogenesis

Retinoic acid, an endogenous metabolite of vitamin A (retinol), possesses striking biological activity akin to a morphogen in developing and regenerating vertebrate limbs. Systemic administration of retinoic acid (RA) to pregnant mammals during the period of limb organogenesis invariably results in dose-dependent dysmorphogenesis. In an attempt to uncover the mode of action of RA in the developing limb bud we analyzed, by HPLC methods, the levels of RA and its metabolic precursor, retinol, in embryonic mouse tissues prior to and following maternal exposure to a teratogenic dose of RA. Detectable levels of both RA and its isomer 13-cis-retinoic acid were found in the limb buds of Day 11 mouse embryos (40 +/- 2 somites). Although retinol was the major retinoid found in ethanolic extracts of either whole embryo or the limb buds, the latter is enriched in RA compared to the whole embryo. This indicated either a higher degree of retinol metabolism or a sequestration of RA in the limb bud compared to the rest of the embryo at this stage of development. A study of the time course of retinoid levels in treated embryos showed that changes occur rapidly, are stable for several hours, and then begin to return to pretreatment levels. After a maternal dose of 10 mg/kg RA, which resulted in a mild degree of limb anomalies, peak RA levels in the limb bud increased 50-fold over the endogenous level; a full 300-fold increase was found after a 100 mg/kg dose which results in 100% incidence of phocomelia. Interestingly, a dose-dependent depression in retinol levels was observed after RA treatment both in maternal plasma as well as the embryo. Studies are in progress to trace the intracellular disposition of both retinol and RA as well as any further active metabolite of RA in the limb buds and other embryonic tissues.

Selective stimulation of in vitro limb-bud chondrogenesis by retinoic acid

Embryonic exposure to pharmacologic doses of vitamin A analogs (retinoids) is a well-known cause of limb-skeletal deletions, limb truncation and other skeletal malformations. The exclusively inhibitory effect of retinoic acid (RA) on chondrogenesis in standard serum-containing cultures of limb-bud mesenchymal cells is equally well known and has provided a means to explore the cellular basis for RA-mediated skeletal teratogenesis. Recent studies showing that lower RA concentrations can cause skeletal duplication when applied directly to the anterior border of a developing limb, suggest that RA may have a role in normal limb development as a diffusible morphogen capable of regulating skeletal pattern. While RA treatment causes both, skeletal deletions and duplications are clearly different (if not opposing) effects, the latter of which is difficult to reconcile with RA's heretofore exclusively inhibitory effect on in vitro chondrogenesis. In the present study. RA's effects on chondrogenesis and myogenesis were examined in serum-free cultures of chick limb-bud mesenchymal cells and compared with its effects on similar cultures grown in serum-containing medium. When added to serum-free medium, concentrations of RA known to cause skeletal duplication in vivo dramatically enhanced in vitro chondrogenesis (to over 200% of control values) as judged by both Alcian-blue staining and [35S]sulfate incorporation, while having little effect on myogenesis. Higher concentrations inhibited both chondrogenesis and myogenesis. The results indicate that at physiological concentrations. RA can selectively modulate chondrogenic expression and suggest that at higher concentrations, RA's inhibitory effects are less specific.(ABSTRACT TRUNCATED AT 250 WORDS)

Cellular retinoic acid binding protein: detection and quantitation in regenerating axolotl limbs

The concentrations of apo (unoccupied), holo (occupied), and total cellular retinoic acid binding protein (CRABP) were measured at various stages of axolotl limb regeneration. The ratio of apo-CRABP to holo-CRABP declined with advancing regenerate stage until the CRABP was all in the holo form. The increase in holo-CRABP is correlated with a stage-dependent shift in the effect of exogenous retinoic acid on regenerate pattern, from pattern duplication to inhibition of regeneration. The data suggest, though they do not prove, that these different morphological effects could be due to a shift from a CRABP-dependent to a CRABP-independent mechanism of exogenous retinoic acid (RA) action that is related to stage-specific variations in endogenous RA levels.

Transplacental pharmacokinetics of teratogenic doses of etretinate and other aromatic retinoids in mice

The transplacental pharmacokinetics of single teratogenic doses of etretinate and motretinide were compared with particular emphasis on distribution and concentrations in the exposed embryos of the free acid metabolite, etretin. The three aromatic retinoids were also tested for their direct inhibitory effect on chondrogenesis in the limb bud mesenchymal cell "micromass" culture assay. After a standard dose of 100 mg/kg administered on day 11 of gestation in NMRI mice, all three compounds were teratogenic, but they differed from each other in potency. Etretinate was most active as a teratogen, equalling the potency of our standard all-trans-retinoic acid; every exposed fetus was deformed with severe shortening of all limb bones as well as cleft palate. Etretin was less potent than etretinate, and motretinide was considerably less active as a teratogen than the other two. In the in vitro assay, only etretin suppressed chondrogenesis and this activity was equivalent to that of all-trans-retinoic acid (IC50 of 12 ng/ml). Both etretinate and motretinide (which contain an ethyl ester and ethylamide terminal group, respectively) were essentially inactive in vitro, demonstrating the fact that a free carboxylic group may be a requirement for the in vitro suppression of chondrogenesis. These differences between the results obtained in vivo and in vitro could be resolved by pharmacokinetic investigations using HPLC methods. Both etretinate and motretinide were metabolized in vivo to etretin, their likely common teratogenic metabolite. The high teratogenic potency of etretinate was probably the result of high concentrations as well as AUC values of its metabolite etretin in the embryo. On the other hand, the comparatively low teratogenicity of motretinide could be related to approximately 5 x lower embryonic peak levels as well as AUC values of etretin. A comparison of these results with those previously obtained for all-trans- and 13-cis-retinoic acids confirms the correlation between embryonic exposure and teratogenic potency in the mouse. Our results indicate that pharmacokinetic studies are essential for the interpretation of relative teratogenic potencies of retinoids as well as apparent differences between in vivo and in vitro teratogenesis. A free carboxyl group at the terminal end of the tetraene chain was necessary for high activity of the retinoids studied.

Limb bud cell cultures for estimating the teratogenic potential of compounds. Validation of the test system with retinoids

Mesenchyme cells, derived from embryonic limb buds, cultured at high cell density, multiply and differentiate into chondrocytes. Using alcian blue, a stain specific for cartilage proteoglycans, the degree of chondrogenesis can be visualized in the micromass cultures as well as quantified by extraction of the stain and spectrophotometric determination of its absorbance. In the presence of active retinoids chondrogenesis is concentration-dependently inhibited. For comparison of the activity of the various retinoids the concentration needed to reduce alcian blue staining by 50% was estimated. In order to validate whether the activity in limb bud cells can predict the teratogenic potential in vivo, the in vitro activity of 25 retinoids was compared with their in vivo teratogenicity observed mainly in rodents. For retinoids which were already in the biologically active form like those with a free carboxylic acid endgroup, there was a good quantitative correlation between the in vitro and in vivo activity. In contrast, the ethylester analog etretinate was slightly active and the ethylamine analog motretinide inactive in vitro but both were teratogenic in vivo. This finding may indicate that these retinoids were not metabolized to the active form in vitro. In conclusion, these results suggest that the limb bud cell culture system may be useful for a preliminary testing to select non-teratogenic retinoids. For the risk assessment in humans, however, the in vitro result should be verified in animal studies.

Differential effects of 4-hydroperoxycyclophosphamide on limb development in vitro

Cyclophosphamide must be metabolically activated to produce malformations in limbs developing in culture; 4-hydroperoxycyclophosphamide is an analog of the active metabolite of cyclophosphamide, 4-hydroxycyclophosphamide, that breaks down spontaneously in solution to form 4-hydroxycyclophosphamide. To study the mechanism by which metabolites of cyclophosphamide produce limb malformations in vitro we determined the effects of exposure of cultured limb buds to 4-hydroperoxycyclophosphamide. Fore- and hindlimbs were excised from ICR mice on day 12 of gestation and cultured in roller bottles for 6 days. Limbs were exposed to 4-hydroperoxycyclophosphamide for the first 20 hours of the culture period. Addition of 10 micrograms/ml of 4-hydroperoxycyclophosphamide to forelimb or to hindlimb buds in culture produced limb reduction malformations. A dramatic decrease in total limb bone area in fore- and hindlimbs was observed with 10 micrograms/ml of 4-hydroperoxycyclophosphamide. In forelimbs, the long bone area decreased and the paw area remained constant so that the relative contribution of the long bone area to total limb bone area was decreased. In hindlimbs treated with 10 micrograms/ml of 4-hydroperoxycyclophosphamide, no paw skeleton was observed. The DNA, RNA, and protein contents of the limbs were not affected by exposure to 1 microgram/ml of 4-hydroperoxycyclophosphamide, but were decreased by exposure to 10 micrograms/ml of this compound. Exposure to the higher concentration of 4-hydroperoxycyclophosphamide also decreased alkaline phosphatase activity, a marker for osteogenesis, in both fore- and hindlimbs; in contrast, neither concentration of 4-hydroperoxycyclophosphamide had an effect on creatine phosphokinase activity, a marker for myogenesis.(ABSTRACT TRUNCATED AT 250 WORDS)

Modulation of the rabbit chondrocyte phenotype by retinoic acid terminates type II collagen synthesis without inducing type I collagen: the modulated phenotype differs from that produced by subculture

The differentiated phenotype of rabbit articular chondrocytes can be characterized by the synthesis of high levels of cartilage specific proteoglycan and collagen (type II). Treatment of these cells in primary monolayer culture for periods of up to 18 days with 0.03 to 3.0 micrograms/ml retinoic acid (RA) resulted in suppression of colony formation, altered morphology, and decreased (eightfold) proteoglycan and collagen synthesis. With the exception of collagen synthesis, these changes were complete with all doses after 4 days of treatment. Collagen synthesis declined more slowly; it was dose dependent after 4 days and maximally inhibited by all doses by 9 days. Detailed analysis of the collagen phenotype was performed using SDS-PAGE of intact chains and 2-D CNBr peptide analysis. RA caused cessation of type II synthesis, and transient stimulation of type III and type I trimer collagen synthesis, without induction of type I collagen. Essentially identical results were obtained with retinol. The resultant collagen phenotype differed significantly from the type I-containing phenotype induced by subculture. Thus, suppression of this differentiated program did not elicit a common modulated phenotype. The results are discussed in the context of direct and indirect mechanisms of RA-dependent modulation of chondrocyte gene expression.

Retinoic acid enhances and depresses in vitro development of cartilaginous bone anlagen in embryonic mouse limbs

Forelimbs of Day 11 and Day 12 embryonic mice were excised and cultured for 3 d in the presence of either 0.25 microgram (8 X 10(-7) M), 0.5 microgram (1.7 X 10(-6) M), or 1.0 microgram (3.3 X 10(-6) M) of all-trans retinoic acid (RA) per milliliter of culture medium. Cultured limbs were fixed, stained, and mounted whole on glass slides and evaluated with computerized optical image analysis for RA-induced effects on the area and shape of the total limb and individual bone anlagen. Relative effects of RA on total bone, soft tissue, long bone, and paw regions were also examined. With Day 11 forelimbs total bone area was increased by 10.5% by the low dose of RA. The increase was mostly in long bones and at the expense of soft tissue. Total bone area was increased 9.3% with Day 12 forelimbs. This increase was primarily in the paw. The high dose of RA decreased Day 11 forelimb area, primarily affecting long bones. Day 12 forelimbs were not significantly affected by the high dose of RA. Effects of the intermediate dose were primarily limited to reduction in soft tissue area. Long bone:paw and soft tissue:bone ratios reflected these effects. The high dose produced a consistent rounding or shortening of Day 11 forelimb bones. On Day 12 0.5 microgram/ml RA produced an inconsistent pattern of rounding of bone anlagen. Treatment with the high dose on Day 12 produced angular rather than rounded contours in many cases, as indicated by shape factor values closer to zero than obtained with controls. These data show that direct exposure to RA can affect both the size and shape of bone anlagen of the developing limb; the low dose enhances and the high dose depresses development. The results support previous studies which suggest that RA may play a critical role in the control of cell activities such as cell migration, proliferation, and cytodifferentiation in the development of the cartilaginous bone anlagen.

Suppression by the cyclohexanetrione Ro 31-0521 of retinoic acid-induced teratogenicity

The cyclohexanetrione Ro 31-0521, which stimulates prostaglandin synthesis, inhibited retinoic acid-induced cartilage degradation in vitro and suppressed the congenital forelimb malformations in rats treated with retinoic acid on day 13 of gestation in a dose-dependent manner.

Suppression by cyclohexanetriones of retinoic acid-induced cartilage degradation in vitro and teratogenicity in vivo

In cultured fetal rat bones, cyclohexanetriones that stimulate prostaglandin synthesis inhibited retinoic acid-induced cartilage degradation in a dose-dependent manner. The inhibition by the cyclohexanetrione Ro 31-0521 was reversible, indicating that the effect was not due to cytotoxicity. Excess retinoic acid is teratogenic in rats and adversely affects the normal differentiation of various morphogenetic systems, depending on the time of administration. The following retinoic acid-induced malformations were suppressed by Ro 31-0521: malformations of long bones and of apical phalanges induced on days 13 and 15 of gestation, respectively; spina bifida and tail malformations induced on day 11 of gestation and cleft palate induced on day 15 of gestation. However, cleft palate and other head malformations including exencephaly induced by retinoic acid on day 11 of gestation were not suppressed but even increased by Ro 31-0521. At a high dose, Ro 31-0521 given alone on day 11 of gestation was embryolethal and teratogenic but was not on the tested other days, indicating that the cyclohexanetrione at specific stages and doses also interfered with normal morphogenesis like retinoic acid. Assuming that stimulation of prostaglandin synthesis is the main biological effect of the cyclohexanetriones, our findings suggest that prostaglandins may be involved in mediating retinoid action.

Chondrogenesis of limb-bud cells: improved culture method and the effect of the potent teratogen retinoic acid

A new apparatus for the mild and reproducible dissociation of rat limb buds into single cells is described. The growth and differentiation of the embryonic mesenchyme cells into chrondrocytes was markedly affected by the conditions of tissue dissociation and the serum used. The degree of chondrogenesis was assessed by alcian blue staining, specific for cartilage matrix. Retinoic acid, a known teratogen, inhibited chondrogenesis completely in a dose-dependent manner. The determination of the quantifiable end-point, IC50 in this cell-culture system, may be suitable to compare the activity of various retinoids and eventually to determine their teratogenic potential.

Evaluation of the sensitive step of inhibition of chondrogenesis by retinoids in limb mesenchymal cells in vitro

The sensitive step of inhibition of chondrogenesis in vitro by retinoids was investigated in modified micromass cultures of limb bud mesenchymal cells from mouse embryos of day 11 and 12. Evaluation of chondrogenesis was performed after alcian blue staining, using a simple random hit counting of cartilage nodules. All-trans-retinoic acid, 13-cis-retinoic acid, and a newly developed arotinoid, RO 13-6298, were tested for their ability to inhibit chondrogenesis. We found that inhibition of chondrogenesis depended on the dosage and the duration of treatment with the different retinoids. Further analysis showed that chondrogenesis in limb bud mesenchymal cells from the proximal part was irreversibly inhibited after one hour of treatment, whereas distal cells showed a reduction of cartilage development only after a treatment period of 12 and more hours. In respect to the doses of the retinoids, proximal cells were about one magnitude more vulnerable than distal cells. These proximo-distal differences were obtained with 13-cis-retinoic acid at 10 micrograms/ml, with all-trans-retinoic acid at 1 microgram/ml and with arotinoid RO 13-6298 with 10 ng/ml. It is supposed that the late blastemal stage of chondrogenic differentiation before the onset of matrix synthesis is the step which is most vulnerable to retinoid treatment.

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.

Ro 15-1570, a new sulfur-containing retinoid devoid of bone toxicity in rats

Repeated ingestion of high doses of retinoids cause the so-called hypervitaminosis A syndrome. In rats the main symptoms are weight loss, alopecia, erythema, desquamation of the skin, and alterations of the skeletal system, including bone fractures. In the present study, three retinoids (Ro 15-1570, arotinoid ethylsulfone, 6 mg/kg; retinoic acid, 100 mg/kg and etretinate, 50 mg/kg) were administered orally to rats for 1 and 2 weeks, respectively, to six male and six female rats/group. All the above changes were induced by all three retinoids, with the exception that the arotinoid ethylsulfone Ro 15-1570 did not cause bone alterations. The absence of toxic effects on the bones by Ro 15-1570 was confirmed by X-ray-film examinations, densitometry of the X-rayed femora and tibiae, examination of the thickness of the femoral and tibial compacta in histological slides plus the determination of the femoral ash weight and its main inorganic constituents (calcium, magnesium, sodium, and potassium). The present demonstration that the arotinoid ethylsulfone Ro 15-1570 was devoid of bone toxicity constitutes major progress in the pharmacologic development of retinoids with a better balance between therapeutic and adverse effects.

Retinoic acid enhances the displacement of newly synthesized hyaluronate from cell layer to culture medium during early phases of chondrogenesis

Chondrogenic differentiation in mouse limb bud mesenchymal cells cultured at high density was suppressed by supplementation of the medium with retinoic acid (1 microgram/ml or 3.3 X 10(-6) M). Since in control medium overt chondrogenesis begins on day 3, retinoic acid was introduced on day 2 so that the relationship between initial biosynthetic changes and inhibition of chondrogenesis could be studied. During the first 24 h of exposure the treated cells remained viable but suffered 10% inhibition in growth and synthesized [3H]glucosamine-labeled glycosaminoglycan at a level 24% below untreated cells. The amount of labeled hyaluronic acid released into the culture medium by the treated cells was, however, 2-fold greater, on a per cell basis, than that in the untreated cultures. It is suggested that the displacement of hyaluronate may play a role in the disruption of mesenchymal cell differentiation and of limb morphogenesis as observed in other systems.

Comparative teratogenic activities of two retinoids: effects on palate and limb development

Two closely related retinoids, all-trans and 13-cis retinoic acids, were assessed for their relative activities as teratogens in ICR mice by monitoring the frequency with which either isomer produced discrete dysmorphogenesis of the embryonic limb and the secondary palate. A single oral dose of all-trans retinoic acid at 100 mg/kg on either day 11.5 or 12.0 of gestation (plug day = day one) was maximally effective; more than 90% of the treated embryos developed reduction defects of the limb bones and an equally high percentage also had cleft palate. The limb development was most sensitive on day 11.5 of gestation while the peak susceptibility for palatal clefts began on day 12.0. Under identical experimental conditions, treatment with 100 mg/kg 13-cis retinoic acid produced no apparent teratogenic effects. By assessing the relative incidence of readily identifiable malformations of the limb and palate associated with various doses of the two isomers, we found that 13-cis retinoic acid was four to eight times less embryopathic than all-trans retinoic acid. Since the mechanism of teratogenic action of retinoids is still far from clear, it is suggested that further studies on causative factors will be greatly assisted by the use of these two closely related retinoids, which substantially differ from each other in their teratogenic potency.

Histological changes during regression induced by retinoic acid in a transplantable rat chondrosarcoma

Daily oral treatment with retinoic acid (100 mg/kg bodyweight) induced regression of a transplantable rat chondrosarcoma. In a previous biochemical investigation we have shown that the tissue breakdown is preceded by the loss of proteoglycan. The present study describes the histological changes induced by retinoic acid. A decrease in the intensity of metachromatic staining with toluidine blue was noted already after 1 day and the discoloration was almost complete after 4 days correlating with the loss of proteoglycan. Especially in the perichondrium there was a rapid proliferation of fibroblasts and monocytes. Osteoclast-like cells were missing, but tumor nodules were eroded and split up by penetrating perichondrium. After 4 days of treatment larger necrotic areas were found, initially in the center of tumor nodules only. In other areas the majority of tumorous chondroblasts survived. Tumor nodules appeared partly mesenchyma-like with some fibroblast-like cells suggesting a dedifferentiation of chondroblasts by retinoic acid. we believe that tumor regression induced by retinoic acid involved proteoglycan degradation by chondroblasts themselves and chondroclast-like activity of monocytes and fibroblasts.

Retinoic acid-induced cartilage resorption: induction of specific changes in protein synthesis and inhibition by tunicamycin

The addition of retinoic acid to fetal rat bones in culture induces the release of proteoglycans followed by cartilage resorption. In this system retinoic acid markedly suppressed 3H-leucine and 3H-mannose incorporation into acid-precipitable macromolecules, and specifically changed the 3H-leucine incorporation pattern as revealed by gel electrophoresis. Tunicamycin, which selectively inhibits glycosylation of the asparagine residues in proteins, prevented the cartilage cell degradation in response to retinoic acid. Inhibitors of DNA synthesis did not affect the retinoic acid-induced changes indicating that cell division was not required for the cartilage degradation processes induced by retinoic acid. In consideration of our previous and present demonstrations that retinoic acid-induced cartilage resorption required RNA, protein, and glycoprotein synthesis and specifically changed the protein synthesis pattern, we suggest that retinoic acid may exert its action by altering gene expression.