Retinoic acid resistance of the variant embryonal carcinoma cell line RAC65 is caused by expression of a truncated RARα

P19 embryonal carcinoma (EC) cells differentiate when treated with retinoic acid (RA). The P19 EC-derived mutant cell line RAC65 is resistant to the differentiation-inducing activity of RA. We show that these cells express a truncated retinoic acid receptor alpha(mRAR alpha-RAC65), probably due to the integration of a transposon-like element in the RAR alpha gene. This receptor lacks 71 C-terminal amino acids and terminates in the ligand-binding domain. In CAT assays in RAC65 cells, mRAR alpha-RAC65 fails to trans-activate the RAR beta promoter, which contains a RA-response element. In wild-type P19 EC cells mRAR alpha-RAC65 functions as a dominant-negative repressor of RA-induced RAR beta activation. Gel retardation assays demonstrate that mRAR alpha-RAC65 is still able to bind to the RA-response element of the RAR beta promoter, indicating that competition with functional RARs for the same binding site leads to the observed dominant-negative effect. In addition, in two RAC65 clones in which wild-type hRAR alpha was stably transfected RA-sensitivity was restored and in one RAR beta expression could be induced by RA. Taken together, these data show that the primary cause of RA-resistance of RAC65 cells is the expression of a defective RAR alpha, which prevents the trans-activation of RA-responsive genes and results in a loss of the ability to differentiate.     

Retinoic acid-induced changes in differentiation-defective embryonal carcinoma RAC65 cells.

RAC65 is a mutant clone of mouse embryonal carcinoma cells, P19, which does not undergo terminal differentiation upon treatment with retinoic acid (RA). RAC65 cells express a truncated RA receptor alpha (RAR alpha) which, however, does not fully explain their defect. Here we show that RAC65 cells exhibit an additional defect in RAR alpha mRNA which may reflect a defect in RNA splicing. The parental and mutant cells also differ in their capacities to bind [3H]RA into nuclear fractions and in expression of cellular RA binding protein (CRABP) mRNA after treatment with RA. The combined data suggest that the defect in RAC65 RAR alpha results in reduced expression of the CRABP gene after RA treatment and, therefore, increased flow of RA into the nucleus.     

Aggregation and cell cycle dependent retinoic acid receptor mRNA expression in P19 embryonal carcinoma cells.

Differentiation of P19 EC cells along different pathways into derivatives resembling cells of the three embryonic germ layers is accompanied by characteristic differences in modulation of expression of each of the three retinoic acid receptor genes, RAR alpha, -beta and -gamma. Differentiation induced by addition of RA to P19 EC cells cultured in monolayer is accompanied by a rapid increase in expression of both RAR alpha and -beta. Induction of RAR beta occurs in a characteristic biphasic manner, suggesting that multiple factors and/or different mechanisms are involved in controlling its expression. RAR beta mRNA is induced to a far higher level during early aggregation in the presence of RA than during early differentiation in monolayer, suggesting that the direction of differentiation depends on the number and/or ratio of alpha and beta type of RA receptors. Aggregation of P19 EC cells in the presence of RA, but not DMSO, is accompanied by repression of RAR gamma, suggesting that the expression of RAR beta and RAR gamma during neuroectodermal differentiation is mutually exclusive. The effects of RA on RAR expression are significantly greater in G1 than in S-phase of the cell cycle. These results extend previous observations that commitment to differentiation is cell cycle dependent and indicates that critical target gene regulation in response to RA has to take place in G1 for differentiation to occur.     

Cell-cell interaction can influence drug-induced differentiation of murine embryonal carcinoma cells

When cultured in the presence of either retinoic acid (RA) or dimethyl sulfoxide (DMSO), aggregates of the P19 line of mouse embryonal carcinoma (EC) cells differentiate and the spectrum of cell types formed depends on the drug dose. It is shown here the EC cells rapidly lose their colony-forming ability when cultured as aggregates in the presence of DMSO. This loss of plating efficiency (PE) also occurs rapidly following RA treatment. Loss of PE has been used as a quantitative procedure for assessing the rate of drug-induced differentiation. The relationship between drug dose and loss of PE is much steeper for DMSO than for RA, suggesting that these two drugs affect different stages of the differentiation decision-making apparatus. Mutant EC cell lines (D3 and RAC65) do not differentiate in the presence of drug-inducers (DMSO and RA, respectively). Neither differentiation-deficient mutant has an altered ability to form gap junctions. When D3 and P19 cells were mixed within the same DMSO-treated aggregates, the D3 cells remained undifferentiated and the P19 cells differentiated much less efficiently than if they were cultured in the absence of the D3 cells. When RAC65 and P19 cells were mixed in RA-treated aggregates, each cell responded to the drug as though the other were absent. Thus RA behaves as a cell-autonomous inducer of differentiation, whereas DMSO-induced differentiation seems to be mediated by interactions between neighboring cells.     

Targeted disruption of retinoic acid receptor alpha (RAR alpha) and RAR gamma results in receptor-specific alterations in retinoic acid-mediated differentiation and retinoic acid metabolism.

F9 embryonic teratocarcinoma stem cells differentiate into an epithelial cell type called extraembryonic endoderm when treated with retinoic acid (RA), a derivative of retinol (vitamin A). This differentiation is presumably mediated through the actions of retinoid receptors, the RARs and RXRs. To delineate the functions of each of the different retinoid receptors in this model system, we have generated F9 cell lines in which both copies of either the RAR alpha gene or the RAR gamma gene are disrupted by homologous recombination. The absence of RAR alpha is associated with a reduction in the RA-induced expression of both the CRABP-II and Hoxb-1 (formerly 2.9) genes. The absence of RAR gamma is associated with a loss of the RA-inducible expression of the Hoxa-1 (formerly Hox-1.6), Hoxa-3 (formerly Hox-1.5), laminin B1, collagen IV (alpha 1), GATA-4, and BMP-2 genes. Furthermore, the loss of RAR gamma is associated with a reduction in the metabolism of all-trans-RA to more polar derivatives, while the loss of RAR alpha is associated with an increase in metabolism of RA relative to wild-type F9 cells. Thus, each of these RARs exhibits some specificity with respect to the regulation of differentiation-specific gene expression. These results provide an explanation for the expression of multiple RAR types within one cell type and suggest that each RAR has specific functions.     

Control of retinoic acid receptor expression in mouse melanoma cells by cyclic AMP

Retinoic acid receptor (RAR) α and γ mRNAs were constitutively expressed in B16 melanoma cells with or without retinoic acid (RA) treatment. RARβ mRNA, however, was significantly expressed only after exposure to RA. Induction of RARβ by RA occurred within 1 h and was not inhibited by cycloheximide (i.e., did not require new protein synthesis). All three RAR mRNA levels were dramatically decreased with 8-bromo-cyclic AMP treatment and could not be rescued by addition of RA. Analysis of RARγ revealed that this decrease occurred within 1 h of exposure to 8-bromo-cyclic AMP and was not blocked by simultaneous treatment with cycloheximide. The stability of RARγ mRNA was not altered by cyclic AMP treatment. Nuclear extracts from 8-bromo-cyclic AMP-treated cells showed a large decrease in protein binding to a retinoic acid response element (RARE) oligonucleotide compared to control cells. This correlated with a marked reduction of RA-stimulated RARE-reporter gene activity in transfected cells which were treated with cyclic AMP. Pretreatment of B16 cells with cyclic AMP prior to RA addition dramatically reduced induction of PKCα, an early marker of RA-induced cell differentiation. Thus, cyclic AMP can antagonize the action of RA most likely via its ability to inhibit RAR expression. © 1996 Wiley-Liss, Inc.     

Characterization of a retinoic acid responsive element isolated by whole genome PCR.

We have used whole PCR in an attempt to isolate novel retinoic acid (RA) responsive genes. We cloned several small genomic fragments from total human DNA containing putative retinoic acid responsive elements (RAREs) selected by direct binding to the retinoic acid receptor alpha (RAR alpha). We report here that an oligonucleotide containing a sequence from one of the cloned human DNA fragments, and referred to as alpha 1, functions as an authentic RARE. It is shown that both RAR alpha and RAR beta produced in Cos cells as well as in vitro translated RAR alpha bind directly and sequence-specifically to the alpha 1RARE. By mutational analysis it is demonstrated that the alpha 1RARE consists of an imperfect direct repeat of the estrogen- and thyroid hormone-related AGGTCA half-site motif separated by a 5 bp spacer. The orientation and spacing of the half-site repeats are shown to play a critical role in RAR recognition. When cloned upstream of a TK-Luc reporter, the alpha 1RARE is shown to confer responsiveness to RA in an orientation-independent fashion in F9 and CV-1 cells. The magnitude of the RA response mediated by the alpha 1RARE differed in these cell lines.     

The prevention of adipose differentiation of 3T3-L1 cells caused by retinoic acid is elicited through retinoic acid receptor alpha

Retinoids, especially all-trans retinoic acid (RA), have been shown to inhibit the differentiation of preadipose cells. It is important to human health, especially to obesity, that the regulatory system for the differentiation of adipocytes is well defined. Previously, we have shown that retinoic acid receptor (RAR) γ2 gene expression is up-regulated by RA in 3T3-L1 preadipose cells. In this study, the RAR system was dissected and the RA-regulated function in 3T3-L1 cells was assigned to one given receptor. We used three synthetic retinoids; (1) Ro 41–5253, a selective RAR α antagonist, (2) Ch 55, an RAR α, β and γ agonist, and (3) Am 80, an RAR α and β agonist, which has less affinity to RAR γ. Ro 41–5253 reverted RA-induced inhibition of the differentiation of 3T3-L1 cells. However, there was no significant reversion in RA-induced RAR γ mRNA level by treatment with Ro 41–5253. In the case of RAR agonists, both Am 80 and Ch 55 strongly inhibited the differentiation of 3T3-L1 cells. However, Am 80 weakly increased RAR γ mRNA content less than did Ch 55. These findings suggest, that RAR α is involved in the prevention of adipose differentiation by RA in 3T3-L1 cells. Moreover, there seems no causal relationship between the prevention of adipose differentiation by RA and the up-regulation of RAR γ2 gene expression by RA in 3T3-L1 cells. We have shown the functional heterogeneity of RA action through different RARs in 3T3-L1 cells.