The active derivative of vitamin A, retinoic acid (RA), is essential for normal embryonic development. The spatio-temporal distribution of embryonic RA results from regulated expression of RA-synthesizing retinaldehyde dehydrogenases and RA-metabolizing cytochrome P450s (CYP26). Excess RA administration or RA deficiency results in a complex spectrum of embryonic abnormalities. As a first step in understanding the developmental function of RA-metabolizing enzymes, we have disrupted the murine Cyp26A1 gene. We report that Cyp26A1-null mutants die during mid-late gestation and show a number of major morphogenetic defects. Spina bifida and truncation of the tail and lumbosacral region (including abnormalities of the kidneys, urogenital tract, and hindgut) are the most conspicuous defects, leading in extreme cases to a sirenomelia ("mermaid tail") phenotype. Cyp26A1 mutants also show posterior transformations of cervical vertebrae and abnormal patterning of the rostral hindbrain, which appears to be partially posteriorly transformed. These defects correlate with two major sites of Cyp26A1 expression in the rostral neural plate and embryonic tail bud. Because all of the Cyp26A1 −/− abnormalities closely resemble RA teratogenic effects, we postulate that the key function of CYP26A1 is to maintain specific embryonic areas in a RA-depleted state, to protect them against the deleterious effect of ectopic RA signaling.
We have cloned a mouse cDNA homolog of P450RAI, a cytochrome P450 belonging to a new family (CYP26), which has previously been isolated from zebrafish and human cDNAs and found to encode a retinoic acid-inducible retinoic acid hydroxylase activity. The crossspecies conservation of the amino acid sequence is high, particularly between the mouse and the human enzymes, in which it is over 90%. Like its human and zibrafish counterparts, the mouse P450RAI cDNA catalyzes metabolism of retinoic acid into 4-OH-retinoic acid, 4-oxo-retinoic acid, 18-OH-retinoic acid, and unidentified water-soluble metabolites when transfected into COS-1 cells. Retinoic acid-inducible retinoic acid metabolism has previously been observed in F9 murine embryonal carcinoma cells and some derivatives lacking retinoid receptors. We were interested in determining whether P450RAI could be responsible for retinoic acid metabolism in F9 cells and in studying the effect of retinoid receptor ablation on P450RAI expression. In wild-type F9 cells and derivatives lacking RAR␥, RAR␣, and/or RXR␣, we observed a direct relationship between the level of retinoic acid metabolic activity and retinoic acid-induced P450RAI mRNA. These experiments, as well as others using synthetic receptor subtype-specific retinoids, suggest that the RAR␥ and RXR␣ receptors mediate the effects of retinoic acid on the expression of the P450RAI gene.
Dietary deprivation and gene disruption studies clearly demonstrate that biologically active retinoids, such as retinoic acid (RA), are essential for numerous developmental programs. Similar ontogenic processes are also affected by retinoic acid excess, suggesting that the effects of retinoid administration reflect normal retinoid-dependent events. In the mouse, exogenous retinoic acid can induce both anterior (anencephaly, exencephaly) and posterior (spina bifida) neural tube defects depending on the developmental stage of treatment. Retinoic acid receptor gamma (RARgamma) mediates these effects on the caudal neural tube at 8.5 days postcoitum, as RARgamma-/- mice are completely resistant to spina bifida induced by retinoic acid at this stage. We therefore used this null mouse as a model to examine the molecular nature of retinoid-induced caudal neural tube defects by using a panel of informative markers and comparing their expression between retinoic acid-treated wild-type and RARgamma-/- embryos. Our findings indicate that treatment of wild-type embryos led to a rapid and significant decrease in the caudal expression of all mesodermal markers examined (e.g., brachyury, wnt-3a, cdx-4), whereas somite, neuroepithelial, notochord, floorplate, and hindgut markers were unaffected. RARgamma-/- mutants exhibited normal expression patterns for all markers examined, consistent with the notion that mesodermal defects underlie the etiology of retinoid-induced spina bifida. We also found that posterior somitic, but not caudal presomitic, embryonic tissues contained detectable bioactive retinoids, an observation which correlated with the ability of caudal explants to rapidly clear exogenous RA. Interestingly, transcripts encoding mP450RAI, a cytochrome P450, the product of which is believed to catabolize retinoic acid, were abundant in the retinoid-poor region of the caudal embryo. mP450RAI was rapidly induced by retinoic acid treatment in vivo, consistent with previous studies suggesting that it plays a critical role in retinoid signaling. These data suggest that nascent mesoderm is highly sensitive to retinoic acid and that mP450RAI serves to tightly regulate retinoid levels in the caudal embryo. These findings also raise the possibility that RA may play a role in the generation of posterior mesoderm derivatives in part by affecting brachyury expression.
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