Retinoids enhance glucocorticoid-induced apoptosis of T cells by facilitating glucocorticoid receptor-mediated transcription.

Glucocorticoid-induced apoptosis of thymocytes is one of the first recognized forms of programmed cell death. It was shown to require gene activation induced by the glucocorticoid receptor (GR) translocated into the nucleus following ligand binding. In addition, the necessity of the glucocorticoid-induced, but transcription-independent phosphorylation of phosphatidylinositol-specific phospholipase C (PI-PLC) has also been shown. Here we report that retinoic acids, physiological ligands for the nuclear retinoid receptors, enhance glucocorticoid-induced death of mouse thymocytes both in vitro and in vivo. The effect is mediated by retinoic acid receptor (RAR) alpha/retinoid X receptor (RXR) heterodimers, and occurs when both RARα and RXR are ligated by retinoic acids. We show that the ligated RARα/RXR interacts with the ligated GR, resulting in an enhanced transcriptional activity of the GR. The mechanism through which this interaction promotes GR-mediated transcription does not require DNA binding of the retinoid receptors and does not alter the phosphorylation status of Ser232, known to regulate the transcriptional activity of GR. Phosphorylation of PI-PLC was not affected. Besides thymocytes, retinoids also promoted glucocorticoid-induced apoptosis of various T-cell lines, suggesting that they could be used in the therapy of glucocorticoid-sensitive T-cell malignancies.

[Genetic dissection of retinoic acid function in epidermis physiology]. / Dissection génétique de la fonction de l'acide rétinoïque dans la physiologie de l'épiderme.

The active metabolite of vitamin A (retinoic acid, RA) acts through the nuclear receptors RARalpha, beta and gamma and RXRalpha, beta and gamma. These receptors form RAR/RXR heterodimers, which bind to genetic regulatory DNA sequences and activate transcription of RA target genes. As RXR form heterodimers with a number of other nuclear receptors, such as the vitamin D3 receptor (VDR) and are involved in several signaling pathways. In the skin, RARgamma and RXRalpha predominate, but RARalpha and RXRbeta are also expressed. To elucidate the role of RA in skin physiology, we produced mutant mouse lines null for RAR or RXR. On the one hand, null mutations for RARa or RXRbeta have no effect on the skin, whereas a RARgamma-null mutation induces alterations in the granular cell layer. On the other, genetic inactivation of RXRa leads to embryonic lethality before epidermal development. Consequently, to determine the role of RXRa in adult mice, studies were performed using conditional somatic mutagenesis (permitting inactivation of a given gene in a specific tissue and in a time-dependent manner). Using this novel genetic approach, mutant mice were obtained in which RXRalpha was not expressed in the skin. These mice developed hair follicle degeneration, then alopecia, similar to that observed in VDR-null mutants, suggesting that hair follicle homeostasis depends on RXRalpha/VDR heterodimers. A similar genetic approach applied to the RARgamma locus demonstrated that topical administration of RA on the skin activates RARgamma/RXR heterodimers in suprabasal cells, and induces expression of a paracrine growth factor (HB-EGF) in these cells which, in turn, stimulates the proliferation of basal cells.

Roles of retinoic acid receptors in early embryonic morphogenesis and hindbrain patterning.

Mutants mice carrying targeted inactivations of both retinoic acid receptor (RAR) alpha and RAR gamma (A alpha/A gamma mutants) were analyzed at different embryonic stages, in order to establish the timing of appearance of defects that we previously observed during the fetal period. We show that embryonic day (E)9.5 A alpha/A gamma embryos display severe malformations, similar to those already described in retinaldehyde dehydrogenase 2 null mutants. These malformations reflect early roles of retinoic acid signaling in axial rotation, segmentation and closure of the hindbrain; formation of otocysts, pharyngeal arches and forelimb buds; and in the closure of the primitive gut. The hindbrain of E8.5 A alpha/A gamma embryos shows a posterior expansion of rhombomere 3 and 4 (R3 and R4) markers, but fails to express kreisler, a normal marker of R5 and R6. This abnormal hindbrain phenotype is strikingly different from that of embryos lacking RAR alpha and RAR beta (A alpha/A beta mutants), in which we have previously shown that the territory corresponding to R5 and R6 is markedly enlarged. Administration of a pan-RAR antagonist at E8.0 to wild-type embryos cultured in vitro results in an A alpha/A beta-like hindbrain phenotype, whereas an earlier treatment at E7.0 yields an A alpha/A gamma-like phenotype. Altogether, our data suggest that RAR alpha and/or RAR gamma transduce the RA signal that is required first to specify the prospective R5/R6 territory, whereas RAR beta is subsequently involved in setting up the caudal boundary of this territory.

Differential contributions of AF-1 and AF-2 activities to the developmental functions of RXR alpha.

We have engineered a mouse mutation that specifically deletes most of the RXR alpha N-terminal A/B region, which includes the activation function AF-1 and several phosphorylation sites. The homozygous mutants (RXR alpha af1(o)), as well as compound mutants that further lack RXR beta and RXR gamma, are viable and display a subset of the abnormalities previously described in RXR alpha-null mutants. In contrast, RXR alpha af1(o)/RAR(-/-)(alpha, beta or gamma) compound mutants die in utero and exhibit a large array of malformations that nearly recapitulate the full spectrum of the defects that characterize the fetal vitamin A-deficiency (VAD) syndrome. Altogether, these observations indicate that the RXR alpha AF-1 region A/B is functionally important, although less so than the ligand-dependent activation function AF-2, for efficiently transducing the retinoid signal through RAR/RXR alpha heterodimers during embryonic development. Moreover, it has a unique role in retinoic acid-dependent involution of the interdigital mesenchyme. During early placentogenesis, both the AF-1 and AF-2 activities of RXR alpha, beta and gamma appear to be dispensable, suggesting that RXRs act as silent heterodimeric partners in this process. However, AF-2 of RXR alpha, but not AF-1, is required for differentiation of labyrinthine trophoblast cells, a late step in the formation of the placental barrier.

Systematic immunolocalization of retinoid receptors in developing and adult mouse eyes.

PURPOSE: To determine the localization of retinoic acid receptors (RAR) alpha, beta, and gamma and retinoid X receptors (RXR) alpha, beta, and gamma in developing and adult mouse eyes at the level of single cells. METHODS: Immunohistochemistry was performed on paraformaldehyde-lysine-periodate-fixed cryosections of mouse eyes, from embryonic day 10.5 to adulthood, with polyclonal antibodies directed against each receptor isoform. Histologic sections from null mutant mice for each receptor served as negative controls. RESULTS: RARalpha was present ubiquitously in the prenatal eye and preferentially located in the posnatal retina and ciliary body. RARbeta was detected predominantly in the periocular mesenchyme and ciliary body. RARgamma was distributed in the periocular mesenchyme, choroid, sclera, cornea, conjunctiva, and lids. RXRalpha was found preferentially in the prenatal periocular mesenchyme and retina and in the postnatal ciliary body, cornea, and conjunctiva. RXRbeta was ubiquitous at all the stages. RXRgamma was detected mainly in subsets of prenatal retinal cells and in postnatal ganglion cells as well as a subset of photoreceptor cells that were characterized as cones in adults. CONCLUSIONS: RARalpha, beta, and gamma and RXRalpha and gamma exhibit specific and dynamic patterns of distribution in ocular tissues throughout the course of development. The abundance of RARbeta, RARgamma, and RXRalpha in the periocular mesenchyme suggests that this tissue represents an important site of retinoid actions during eye development and in adulthood.

Genomic structure and chromosomal mapping of the gene coding for ICBP90, a protein involved in the regulation of the topoisomerase IIalpha gene expression.

We have recently identified a novel CCAAT box binding protein (ICBP90) involved in the regulation of topoisomerase IIalpha gene expression. We have observed that it is expressed in non-tumoral proliferating human lung fibroblast cells whereas in HeLa cells, a tumoral cell line, ICBP90 was still present even when cells were at confluence. In the present study, we have determined the ICBP90 gene structure by screening of a human placenta genomic library and PCR analysis. We report that the ICBP90 gene spans about 35.8 kb and contains six coding exons named A to F. In the 5' upstream sequence of the region containing the coding exons, two additional exons (I and II) were found. Additionally, an internal splicing site was found in exon A. A promoter region, including three putative Sp1 binding sites between exons I and A, was identified by transient transfection. Northern blot analysis of several cancer cell lines revealed the existence of two ICBP90 mRNA species of 5.1 and 4.3 kb that are transcribed from the gene. The relative amounts of these mRNAs depended on the cell type. In MOLT-4 cells and Burkitt's lymphoma Raji cells, the 4.3 kb or the 5.1 kb transcripts were mainly observed, respectively. In other cell lines, such as HL-60 cells, chronic myelogenous leukaemia K-562, lung carcinoma A549, HeLa or colorectal SW480, both 4.3 and 5.1 kb forms of ICBP90 mRNA could be detected. Interestingly, western blot analysis showed several ICBP90 protein bands in HeLa but only a single band in MOLT-4 cell extracts. Taken together our results are consistent with the ICBP90 gene exhibiting alternative splicing and promoter usage in a cell-specific manner.

Positive and negative regulation of granulopoiesis by endogenous RARalpha.

Acute promyelocytic leukemia (APL) is always associated with chromosomal translocations that disrupt the retinoic acid receptor alpha (RARalpha) gene. Whether these translocations relate to a role for endogenous RARalpha in normal granulopoiesis remains uncertain because most studies addressing this question have used non-physiological overexpression systems. Granulocyte differentiation in cells derived from RARalpha-deficient (RARalpha(-/-)) mice was studied and evaluated in the context of agonist-bound and ligand-free RARalpha. Our results demonstrate that RARalpha is dispensable for granulopoiesis, as RARalpha(-/-) mice have a normal granulocyte population despite an impaired ability to respond to retinoids. However, although it is not absolutely required, RARalpha can bidirectionally modulate granulopoiesis. RARalpha stimulates differentiation in response to exogenous retinoic acid. Furthermore, endogenous retinoids control granulopoiesis in vivo, as either vitamin A-deficient mice or animals treated with an RAR antagonist accumulate more immature granulocytes in their bone marrow. Conversely, RARalpha acts to limit differentiation in the absence of ligand because granulocyte precursors from RARalpha(-/-) mice differentiate earlier in culture. Thus, the block in granulopoiesis exerted by RARalpha fusion proteins expressed in APL cells may correspond to an amplification of a normal function of unliganded RARalpha.

Retinoic acid receptor-beta: an endogenous inhibitor of the perinatal formation of pulmonary alveoli.

Pulmonary alveoli are formed, in part, by subdivision (septation) of the gas-exchange saccules of the immature lung. Septation is developmentally regulated, and failure to septate at the appropriate time is not followed by delayed spontaneous septation. We report retinoic acid receptor (RAR) beta knockout mice exhibit premature septation; in addition, they form alveoli twice as fast as wild-type mice during the period of septation but at the same rate as wild-type mice thereafter. Consistent with the perinatal effect of RARbeta knockout, RARbeta agonist treatment of newborn rats impairs septation. These results 1) identify RARbeta as the first recognized endogenous signaling that inhibits septation, 2) demonstrate premature onset of septation may be induced, and 3) show the molecular signaling regulating alveolus formation differs during and after the period of septation. Suppressing perinatal RARbeta signaling by RARbeta antagonists may offer a novel, nonsurgical, means of preventing, or remediating, failed septation in prematurely born children.

Stage-dependent responses of the developing lung to retinoic acid signaling.

Morphological analysis of vitamin A-deficient rat fetuses and of retinoic acid receptor (RAR and RXR) mutant mice have demonstrated that retinoic acid (RA) is essential for lung development. To gainfurther insight into RA signaling pathways during primary lung budformation and lung branching, we have investigated the effects of RA and of a pan-RAR antagonist in cultures of whole embryos and lung explants. Treatment of E8.0 embryos with the pan-RAR antagonist inhibits the formation of the primitive respiratory system. On the other hand, treatment of E11.75 and E12.5 lung explants with RA inhibits branching morphogenesis, whereas treatment with the pan-RAR antagonist at the same developmental stages stimulates formation of distal buds. The inhibitory effect of RA on branching is strongly decreased in RARbeta null lungs, while enhancement of budding by the pan-RAR antagonist is not affected by an RARgamma null mutation. Additionally, cellular retinol binding protein one (CRBPI) null lungs are more sensitive than wild type lungs to the pan-RAR antagonist-induced stimulation of branching. These data indicate that retinoid signaling is indispensable for the formation of primary lung buds and the oesophagotracheal septum from the primitive foregut. They also suggest that at the pseudoglandular stage, RA signaling through RARbeta, but not RARgamma, inhibits distal bud formation thereby promoting the formation of conducting airways. Moreover, the level of CRBPI in the pseudoglandular lung appears to participate in the control of branching morphogenesis.

Spatio-temporal distribution of cellular retinoid binding protein gene transcripts in the developing and the adult cochlea. Morphological and functional consequences in CRABP- and CRBPI-null mutant mice.

The expression patterns of the mouse cellular retinoid binding protein genes were investigated by in situ hybridization analysis in the inner ear from 10.5 days post coïtum (dpc) up to the adult stage. The cellular retinoic acid binding protein II (CRABPII) and cellular retinol binding protein I (CRBPI) were present in a widespread and abundant pattern in cochlear structures during embryogenesis. Expression of the cellular retinoic acid binding protein I (CRABPI) is restricted during development in Kölliker's organ whilst cellular retinol binding protein II (CRBPII) is only visible after birth with a ubiquitous distribution in most regions of the cochlea including nervous components. No CRABP or CRBP transcripts were observed in the auditory receptors. Morphological observations of CRBPI- and CRABPI/CRABPII-null mutant fetus at 18.5 dpc do not show any structural modification at the level of the organ of Corti. Furthermore, electrophysiological tests performed by measuring distorsion-product otoacoustic emissions and auditory brainstem evoked responses did not present significant alteration of the auditory function for the different types of mutants. The expression of retinoid binding proteins in cochlear structures during embryogenesis could suggest important roles for these proteins during ontogenesis and morphogenesis of the inner ear. Despite these observations, morphological and functional data from mutant mice did not present obvious modifications of the cochlear structures and auditory thresholds. It is therefore unlikely that CRABPs and CRBPI are directly involved in development of the cochlea and hair cell differentiation.

A genetic dissection of the retinoid signalling pathway in the mouse.

To determine the functions of retinoic acid receptors RAR and RXR, we have systematically knocked-out their genes by homologous recombination in the embryonic stem cells and generated null-mutant mice. This approach has allowed us to perform a genetic dissection of the retinoic acid signalling pathway.

Key roles of retinoic acid receptors alpha and beta in the patterning of the caudal hindbrain, pharyngeal arches and otocyst in the mouse.

Mouse fetuses carrying targeted inactivations of both the RAR(&agr;) and the RARbeta genes display a variety of malformations in structures known to be partially derived from the mesenchymal neural crest originating from post-otic rhombomeres (e.g. thymus and great cephalic arteries) (Ghyselinck, N., Dupé, V., Dierich, A., Messaddeq, N., Garnier, J.M., Rochette-Egly, C., Chambon, P. and Mark M. (1997). Int. J. Dev. Biol. 41, 425-447). In a search for neural crest defects, we have analysed the rhombomeres, cranial nerves and pharyngeal arches of these double null mutants at early embryonic stages. The mutant post-otic cranial nerves are disorganized, indicating that RARs are involved in the patterning of structures derived from neurogenic neural crest, even though the lack of RARalpha and RARbeta has no detectable effect on the number and migration path of neural crest cells. Interestingly, the double null mutation impairs early developmental processes known to be independent of the neural crest e.g., the initial formation of the 3rd and 4th branchial pouches and of the 3rd, 4th and 6th arch arteries. The double mutation also results in an enlargement of rhombomere 5, which is likely to be responsible for the induction of supernumerary otic vesicles, in a disappearance of the rhombomere 5/6 boundary, and in profound alterations of rhombomere identities. In the mutant hindbrain, the expression domain of kreisler is twice its normal size and the caudal stripe of Krox-20 extends into the presumptive rhombomeres 6 and 7 region. In this region, Hoxb-1 is ectopically expressed, Hoxb-3 is ectopically up-regulated and Hoxd-4 expression is abolished. These data, which indicate that retinoic acid signaling through RARalpha and/or RARbeta is essential for the specification of rhombomere identities and for the control of caudal hindbrain segmentation by restricting the expression domains of kreisler and of Krox-20, also strongly suggest that this signaling plays a crucial role in the posteriorization of the hindbrain neurectoderm.

Cellular retinol-binding protein I is essential for vitamin A homeostasis.

The gene encoding cellular retinol (ROL, vitA)-binding protein type I (CRBPI) has been inactivated. Mutant mice fed a vitA-enriched diet are healthy and fertile. They do not present any of the congenital abnormalities related to retinoic acid (RA) deficiency, indicating that CRBPI is not indispensable for RA synthesis. However, CRBPI deficiency results in an approximately 50% reduction of retinyl ester (RE) accumulation in hepatic stellate cells. This reduction is due to a decreased synthesis and a 6-fold faster turnover, which are not related to changes in the levels of RE metabolizing enzymes, but probably reflect an impaired delivery of ROL to lecithin:retinol acyltransferase. CRBPI-null mice fed a vitA-deficient diet for 5 months fully exhaust their RE stores. Thus, CRBPI is indispensable for efficient RE synthesis and storage, and its absence results in a waste of ROL that is asymptomatic in vitA-sufficient animals, but leads to a severe syndrome of vitA deficiency in animals fed a vitA-deficient diet.

Essential roles of retinoic acid signaling in interdigital apoptosis and control of BMP-7 expression in mouse autopods.

We previously reported that mice lacking the RARgamma gene and one or both alleles of the RARbeta gene (i.e., RARbeta+/-/RARgamma-/- and RARbeta-/-/RARgamma-/- mutants) display a severe and fully penetrant interdigital webbing (soft tissue syndactyly), caused by the persistence of the fetal interdigital mesenchyme (Ghyselinck et al., 1997, Int. J. Dev. Biol. 41, 425-447). In the present study, these compound mutants were used to investigate the cellular and molecular mechanisms involved in retinoic acid (RA)-dependent formation of the interdigital necrotic zones (INZs). The mutant INZs show a marked decrease in the number of apoptotic cells accompanied by an increase of cell proliferation. This marked decrease was not paralleled by a reduction of the number of macrophages, indicating that the chemotactic cues which normally attract these cells into the INZs were not affected. The expression of a number of genes known to be involved in the establishment of the INZs, the patterning of the autopod, and/or the initiation of apoptosis was also unaffected. These genes included BMP-2, BMP-4, Msx-1, Msx-2, 5' members of Hox complexes, Bcl2, Bax, and p53. In contrast, the mutant INZs displayed a specific, graded, down-regulation of tissue transglutaminase (tTG) promoter activity and of stromelysin-3 expression upon the removal of one or both alleles of the RARbeta gene from the RARgamma null genetic background. As retinoic acid response elements are present in the promoter regions of both tTG and stromelysin-3 genes, we propose that RA might increase the amount of cell death in the INZs through a direct modulation of tTG expression and that it also contributes to the process of tissue remodeling, which accompanies cell death, through an up-regulation of stromelysin-3 expression in the INZs. Approximately 10% of the RARbeta-/- /RARgamma-/- mutants displayed a supernumerary preaxial digit on hindfeet, which is also a feature of the BMP-7 null phenotype (Dudley et al., 1995, Genes Dev. 9, 2795-2807; Luo et al., 1995, Genes Dev. 9, 2808-2820). BMP-7 was globally down-regulated at an early stage in the autopods of these RAR double null mutants, prior to the appearance of the digital rays. Therefore, RA may exert some of its effects on anteroposterior autopod patterning through controlling BMP-7 expression.

The RXRalpha ligand-dependent activation function 2 (AF-2) is important for mouse development.

We have engineered a mouse mutation that specifically deletes the C-terminal 18 amino acid sequence of the RXRalpha protein. This deletion corresponds to the last helical alpha structure (H12) of the ligand-binding domain (LBD), and includes the core of the Activating Domain of the Activation Function 2 (AF-2 AD core) that is thought to be crucial in mediating ligand-dependent transactivation by RXRalpha. The homozygous mutants (RXRalpha af2(o)), which die during the late fetal period or at birth, exhibit a subset of the abnormalities previously observed in RXRalpha -/- mutants, often with incomplete penetrance. In marked contrast, RXRalpha af2(o)/RXRbeta -/- and RXRalpha af2(o)/RXRbeta -/- /RXRgamma -/- compound mutants display a large array of malformations, which nearly recapitulate the full spectrum of the defects that characterize the fetal vitamin A-deficiency (VAD) syndrome and were previously found in RAR single and compound mutants, as well as in RXRalpha/RAR(alpha, beta or gamma) compound mutants. Analysis of RXRalpha af2(o)/RAR(alpha, beta or gamma) compound mutants also revealed that they exhibit many of the defects observed in the corresponding RXR alpha/RAR compound mutants. Together, these results demonstrate the importance of the integrity of RXR AF-2 for the developmental functions mediated by RAR/RXR heterodimers, and hence suggest that RXR ligand-dependent transactivation is instrumental in retinoid signalling during development.

Nuclear detection of cellular retinoic acid binding proteins I and II with new antibodies.

Apart from the retinoic acid nuclear receptor family, there are two low molecular weight (15 kD) cellular retinoic acid binding proteins, named CRABPI and II. Mouse monoclonal and rabbit polyclonal antibodies were raised against these proteins by using as antigens either synthetic peptides corresponding to amino acid sequences unique to CRABPI or CRABPII, or purified CRABP proteins expressed in E. coli. Antibodies specific for mouse and/or human CRABPI and CRABPII were obtained and characterized by immunocytochemistry and immunoblotting. They allowed the detection not only of CRABPI but also of CRABPII in both nuclear and cytosolic extracts from transfected COS-1 cells, mouse embryos, and various cell lines.

Contribution of retinoic acid receptor beta isoforms to the formation of the conotruncal septum of the embryonic heart.

To investigate the relative contribution of retinoic acid receptor (RAR)beta isoforms in conotruncal septation, RAR beta 1 and beta 3 were inactivated in the mouse. Mice lacking RAR beta 1 and beta 3 appear normal. Disruption of these isoforms in RAR alpha or RAR gamma null genetic backgrounds results in a high postpartum lethality. However, except for ocular defects found in RAR beta 1-3/RAR gamma compound mutants, the double null mutants display only abnormalities seen in single null mutants. This probably reflects a functional redundancy with other RARs, most notably with RAR beta 2 which is five- to sixfold more abundant than RAR beta 1 and beta 3 and whose domain of expression is largely overlapping. The conotruncal ridges form normally in retinoid X receptor (RXR)alpha/RAR beta compound mutants but fail to fuse, apparently as a result of excessive apoptosis of mesenchymal cells. Additionally, many cardiomyocytes in the conotruncal wall of these mutants appear necrotic. Although RAR beta 1 and beta 3 are expressed specifically in the conotruncal ridges, failure of fusion of these structures is not more frequent in RXR alpha/RAR beta 1-3 double null mutants than in RXR alpha single null mutants. Similarly, the disruption of the sole RAR beta 2 isoform in a RXR alpha null genetic background does not result in an increase of the frequency of conotruncal septum agenesis. However, this agenesis is fully penetrant in RXR alpha/RAR beta +/- mutants, which reflects distinct role of RXR alpha:RAR beta 1 (and beta 3) and RXR alpha:RAR beta 2 heterodimers in promoting the survival of conotruncal mesenchymal cells. Unexpectedly, we discovered that, in wild-type embryos, the conotruncal mesenchyme is a major site of morphogenetic cell death and that conotruncal myocytes are occasionally necrotic. Thus, excessive cell death in the conotruncus is a potential cause of ventricular septal defects in humans.

Mesectoderm is a major target of retinoic acid action.

The RAR and RXR families of retinoid nuclear receptors each comprise three isotypes (alpha, beta and gamma). In vitro, RARs bind to their cognate DNA response elements as heterodimers with RXRs. Null mutations of all six isotypes have been generated. The defects displayed by RAR alpha, beta and gamma single null mutant mice are confined to a small subset of the tissues normally expressing these receptors. This discrepancy reflects the existence of a functional redundancy, since RAR double null mutants exhibit congenital malformations in almost every organ system. In particular, most of the structures derived from the mesectoderm are severely affected. Analysis of mutant mice lacking both RARs and RXRs indicates that RXR alpha:RAR gamma heterodimers are instrumental in the patterning of craniofacial skeletal elements, whereas RXR alpha:RAR alpha heterodimers may be preferentially involved in the generation of neural crest cell-derived arterial smooth muscle cells. Both RXR alpha:RAR beta and RXR alpha:RAR gamma heterodimers appear to function during the development of the ocular mesenchyme. Moreover, atavistic reptilian cranial structures are generated in RAR mutants, suggesting that the RA signal has been implicated in the modification of developmental programs in the mesectoderm during evolution.

Impaired locomotion and dopamine signaling in retinoid receptor mutant mice.

In the adult mouse, single and compound null mutations in the genes for retinoic acid receptor beta and retinoid X receptors beta and gamma resulted in locomotor defects related to dysfunction of the mesolimbic dopamine signaling pathway. Expression of the D1 and D2 receptors for dopamine was reduced in the ventral striatum of mutant mice, and the response of double null mutant mice to cocaine, which affects dopamine signaling in the mesolimbic system, was blunted. Thus, retinoid receptors are involved in the regulation of brain functions, and retinoic acid signaling defects may contribute to pathologies such as Parkinson's disease and schizophrenia.

Role of the retinoic acid receptor beta (RARbeta) during mouse development.

Homozygous RAR beta mutants are growth-deficient, but are fertile and have a normal longevity. They display homeotic transformations and malformations of cervical vertebrae and a retrolenticular membrane. This latter abnormality arises from the persistence and hyperplasia of the primary vitreous body. In contrast, we found that abnormalities of cranial nerves IX and X which were previously proposed to be specific features of the RAR beta mutant phenotype (Luo et al., Mech. Dev. 53: 61-71, 1995) occur with the same low penetrance in wildtype littermates. Although the RAR beta protein is expressed at high levels in the striatum and interdigital mesenchyme, the brain and limbs of RAR beta mutants appear morphologically normal. RAR alpha/RAR beta double mutants display numerous visceral abnormalities, most of which are incompatible with post-natal life. The majority of these abnormalities was previously detected in RAR alpha/RAR beta2 mutants with the notable exceptions of agenesis of the stapedial (2nd aortic arch-derived) artery, thymic and spleen agenesis and abnormal inferior vena cava. RAR beta/RAR gamma double mutants show major ocular defects including a shortening of the ventral retina and pre-natal retinal dysplasia, both of which represent the only abnormalities of the fetal vitamin-A deficiency (VAD) syndrome not previously detected in RAR beta2/RAR gamma compound mutants. In addition, RAR beta is apparently functionally redundant with either RAR alpha or RAR gamma for the formation of a small subset of craniofacial skeletal elements, as well as for eyelid development and digit separation. We also provide evidence that, at least in some instances, this phenomenon of functional redundancy between RARs may be an artifactual consequence of gene knock-out.