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¹ Herbert Irving Comprehensive Cancer Center, College of Physicians and Surgeons, Columbia University, New York, NY and ² Department of Pathology, University of the Ryukyus Faculty of Medicine, Okinawa, Japan

Requests for Reprints: I. Bernard Weinstein, Herbert Irving Comprehensive Cancer Center, College of Physicians and Surgeons, Columbia University, HHSC-1509, 701 West 168th Street, New York, NY 10032. Phone: (212) 305-6921; Fax: (212) 305-6889. E-mail: ibw1{at}columbia.edu

	Abstract

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Acyclic retinoid (ACR), a novel synthetic retinoid, has recently been demonstrated by us to inhibit the in vitro growth of human hepatoma cells, and this effect was associated with decreased expression of cell cycle-related molecules. These results, taken together with previous in vitro and clinical studies with ACR, suggest that this agent may be useful in the chemoprevention and therapy of hepatoma and possibly other human malignancies. In the present study, we further examined the molecular effects of ACR on the HepG2 human hepatoma cell line, focusing on the expression of nuclear retinoid receptors and the cell cycle inhibitor protein p21^CIP1. Reverse transcription-PCR assays and Western blot analyses indicated that these cells express retinoic acid receptors (RARs) , ß, and , retinoid X receptors (RXRs) and ß, and peroxisome proliferator-activated receptors (PPAR) mRNA. Treatment with ACR caused a rapid induction within 3 h of RARß mRNA and the related protein, but there was no significant change in the levels of the mRNA or proteins for RARs and , RXRs and ß, and PPAR. There was also a rapid increase in p21^CIP1 mRNA and protein in HepG2 cells treated with ACR, and this induction occurred via a p53-independent mechanism. In transient transfection reporter assays, we cotransfected the retinoic acid response element-chloramphenicol acetyltransferase (CAT) reporter gene into HepG2 cells together with a RARß expression vector. RARß expression markedly stimulated CAT activity (up to about 4-fold) after the addition of ACR. However, CAT activity in the presence of ACR was only about 2-fold higher than that in the absence of ACR, when cells were cotransfected with RARs and or RXR. These findings suggest that the growth inhibitory effects of ACR are mediated at least in part through RARß and that both RARß and p21^CIP1 play critical roles in the molecular mechanisms of growth inhibition induced by ACR.

	Introduction

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Retinoids are a group of structural and functional analogues of vitamin A that exhibit major effects on cell proliferation and differentiation and on pattern formation during development (1). During the past 10 years, there has been increasing evidence that both natural and synthetic retinoids can exert an inhibitory effect on the development of several types of human carcinomas (2, 3). The novel synthetic retinoid, acyclic retinoid (ACR), has been shown to prevent the recurrence of hepatoma after surgical resection of primary tumors (4, 5). In these studies, ACR did not cause the typical toxic effects seen with conventional retinoids (4, 5). This unique agent was also reported to decrease the incidence of carcinogen-induced skin tumors and spontaneous hepatomas in mice (6). ACR was also shown to induce apoptosis in the Huh7 human hepatoma cell line (7). In a recent study, we found that ACR inhibits the growth of the Huh7, Hep3B, and HepG2 human hepatoma cell lines (8). In HepG2 cells, this growth inhibition by ACR was associated with arrest of cells in the G₁ of the cell cycle, early induction of the p21^CIP1 protein, and subsequent reduction in the level of both cyclin D1 protein and mRNA (8). We also demonstrated that ACR inhibits ß-catenin-stimulated cyclin D1 promoter activity in HepG2 cells (8).

The activity of various retinoids, including all-trans-retinoic acid (ATRA) and 9-cis-retinoic acid (9-cis-RA), is thought to be mediated by interactions with two subfamilies of nuclear retinoic acid receptors—retinoic acid receptors (RARs) and retinoid X receptors (RXRs; Ref. 9). These subfamilies both include three distinct subtypes, designated , ß, and , which are encoded by distinct genes (10, 11). All of these receptors are ligand-dependent transcription factors and control the activity of target genes by binding to DNA response elements, including retinoic acid response elements (RAREs; DR5) and retinoid X response elements (DR1; Refs. 9, 12). The RARs bind both ATRA and 9-cis-RA, while the RXRs bind only 9-cis-RA (13). These receptors are also thought to bind a variety of synthetic retinoids, some of which preferentially bind to specific subtypes (3).

Normal oral mucosa epithelial cells express RARs , ß, and and RXR (14–16), while preneoplastic lesions and head and neck squamous cell carcinomas (HNSCCs) often display selective suppression of RARß expression (14, 17, 18). These findings suggest that loss of RARß expression is associated with the development of HNSCCs. Treatment of the human hepatoma cell line with ATRA causes a marked increase in the level of RARß mRNA but not in the level of RAR mRNA (19). However, N-(4-hydroxyphenyl)retinamide (fenretinide) selectively activates transcription of RAR and, to a lesser extent, RARß but not transcription of RAR and RXR in human breast carcinoma cell lines (20). Novel synthetic retinoids that bind selectively to RXRs are termed rexinoids (2). The rexinoids LGD1069 (targretin or bexarotene) and LG100268 are highly effective in rat mammary carcinogenesis prevention model systems (2). LGD1069 also inhibits proliferation of human HNSCC cell lines (21).

These findings suggest that different retinoids can act through different retinoid nuclear receptors to alter the expression of genes that inhibit the growth of cancer cells. Therefore, in the present study, we investigated whether ACR acts through specific nuclear RARs to inhibit the growth of human hepatoma cells by examining cellular levels of the related mRNA and proteins before and after treating the cells with doses of ACR that inhibit the growth of these cells. In parallel studies, we also examined whether ACR acts via specific retinoid receptors in enhancing the transcriptional activity of a RARE-chloramphenicol acetyltransferase (CAT) reporter in transient transfection reporter assays.

The activities of the cell cycle control proteins are negatively regulated by a series of cyclin-dependent kinase inhibitors, including p21^CIP1 (22). A recent study demonstrates that the promoter region of the p21^CIP1 gene contains a functional RARE sequence and that this sequence confers retinoid induction of p21^CIP1 mRNA through RAR-RXR heterodimers (23). Therefore, the p21^CIP1 gene appears to be a retinoid target gene (23). In a recent study, we found that ACR causes rapid induction of the p21^CIP1 protein in HepG2 human hepatoma cell line (8). In addition, p21^CIP1 is a primary response gene in the induction of differentiation of HL-60 human leukemia cells by ATRA (24). Therefore, in the present study, we also examined the effects of ACR on the induction of p21^CIP1 mRNA by carrying out time course study using reverse transcription-PCR (RT-PCR) assays and Northern blot analysis.

	Materials and Methods

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Chemicals
ACR [(2E,4E,6E,10E)-3,7,11,15-tetramethyl-2,4,6,10,14,-hexadecapentaenoic acid; Fig. 1 ; NIK333; Nikken Chemicals Co., Ltd., Tokyo, Japan] was provided by Dr. H. Moriwaki (Gifu University School of Medicine, Gifu, Japan; Ref. 7).

View larger version (14K): [in this window] [in a new window]   Figure 1. Chemical structures of ACR (A), ATRA (B), and vitamin A (C).

Western Blot Analysis
HepG2 cell lysates were prepared with a modified radioimmunoprecipitation assay buffer [150 mM NaCl, 1% NP40, 0.1% SDS, 50 mM Tris-HCl (pH 8.0), 0.5% deoxycholic acid, 1 mM EDTA, 2 mM EGTA, 1 mM DTT, 25% glycerol]. Proteins (50–100 mg) were separated by SDS-PAGE, transferred onto an Immobilon-P transfer membrane (Millipore, Bedford, MA), and incubated with the appropriate antibodies as described previously (8). The primary antibodies used in this study were RARß (sc-552; Santa Cruz Biotechnology, Santa Cruz, CA), p21^CIP1 (Ab-1; Oncogene Research Products, Darmstadt, Germany), and p53 (sc-126, Santa Cruz Biotechnology). Anti-mouse IgG or anti-rabbit IgG antibodies (Amersham Pharmacia Biotech, Buckinghamshire, United Kingdom) were used as the secondary antibodies. Each membrane was developed using an enhanced chemiluminescence detection system (Amersham Pharmacia Biotech).

Transient Transfection CAT Reporter Assay
Reporter assays were performed as described previously (8). HepG2 cells were plated into six-well, 35 mm diameter plates (0.5 x 10⁵ cells/well) in DMEM plus 10% FBS and cultured overnight to allow for cell attachment. The RARE-CAT reporter construct (RARE-CAT) consisting of the RARE and the CAT gene and RARs , ß, and and RXR expression vectors were generously provided by Dr. D. A. Talmage (Institute of Human Nutrition, Columbia University, New York, NY). The pcDNA3 plasmid (Invitrogen, San Diego, CA) was used as a control vector. RARE-CAT (2 µg) reporter was transfected into HepG2 cells. The expression vectors (2.0 µg/assay) were cotransfected as described in the legend of Fig. 3 using the Lipofectin reagent (Invitrogen). After transfection, the HepG2 cells were incubated with ACR (30 µM) or 0.1% DMSO in DMEM plus 10% FBS for 24 h. Cell extracts were then prepared, and each sample was assayed in triplicate using a CAT-ELISA system (Roche Diagnostics GmbH, Mannheim, Germany) according to the manufacturer's instructions. The absorbance was measured using a spectrophotometric microtiter plate reader at 405 nm wavelength. A cytomegalovirus-driven ß-gal expression plasmid was cotransfected with the above plasmids to normalize for transfection efficiency. Differences in reporter activities between the experimental groups were analyzed by Student's t test. All statements of significance are P < 0.05.

View larger version (51K): [in this window] [in a new window]   Figure 3. Effects of ACR on expression of p21CIP1 and p53. A, RT-PCR analysis of p21CIP1 mRNA. HepG2 cells were treated with DMSO (Control) or ACR (20 µM) for the indicated times (15–180 min). RNA was extracted and analyzed by RT-PCR using the primers for p21CIP1 mRNA. B, Northern blot analysis of p21CIP1 mRNA. HepG2 cells were treated with DMSO (Control) or ACR (20 µM) for the indicated times (3–48 h). RNA was extracted and examined by Northern blot analysis using a [-32P]dCTP-labeled p21CIP1 probe. rRNA was used as a loading control. C, Western blot analysis for the p21CIP1 and p53 proteins (upper panels) and RT-PCR analysis of p53 mRNA (lower panels). HepG2 cells were treated with DMSO (Control) or ACR (20 µM) for the indicated times (3–48 h). Protein extracts were examined by Western blot analysis for the p21CIP1 and p53 proteins and RNA extracts were examined by RT-PCR for p53 mRNA. Actin was used as a loading control. Similar results were obtained in repeated studies.

	Results

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ACR Causes a Rapid Increase in the Levels of Expression of RARß mRNA and Protein
In a previous study, we found that ACR inhibits the growth of HepG2 human hepatoma cells, with an IC₅₀ value of about 30 µM when the cells were grown in DMEM containing 10% FBS (8). Therefore, in the present study, we treated HepG2 cells with this concentration of ACR in DMEM plus 10% FBS. We then isolated RNA at 3, 6, 13, and 24 h after the addition of the drug and examined by RT-PCR assays the levels of expression of RARs , ß, and , RXRs , ß, and , and peroxisome proliferator-activated receptors (PPAR) mRNA (Fig. 2A ). We included assays for PPAR mRNA because PPAR heterodimerizes with RXR (9). To quantify the expression levels of mRNA, PCR products were generated during both plateau and log-phase reactions by conducting 32–40 cycles of PCR as described in our recent study (8). With this approach, we found that these products reflect corresponding levels of mRNA by Northern blot assays (8). In samples treated with ACR (30 µM), there was a marked increase in the RARß band intensity within 3 h after the addition of the drug and this increase persisted at the subsequent 6 and 12 h time points (Fig. 2A). Similar results were obtained in samples obtained at 24 and 48 h after drug treatment (data not shown). In contrast, no major changes in the band intensities of the other four nuclear RARs and of PPAR were seen in cells treated with the same dose of ACR, although some decrease in RAR was seen at 3 and 6 h (Fig. 2A). The expression of RXR mRNA was not detected in these cells (Fig. 2A).

View larger version (45K): [in this window] [in a new window]   Figure 2. Effects of ACR on expression of nuclear receptors. A, RT-PCR analysis of nuclear receptor mRNA. HepG2 cells were treated with DMSO (Control) or ACR (30 µM) for 3, 6, and 12 h. RNA samples were then analyzed by RT-PCR using the pairs of primers shown in Table 1. Actin was used as an internal control. B, RARß protein expression in HepG2 cells after treatment with DMSO (Control) or ACR. Cells were treated as described above and protein extracts were examined for RARß expression by Western blot analysis. C, RT-PCR analysis of RARß mRNA. RNA was prepared from HepG2 cells treated with DMSO (Control) or ACR for the indicated periods of time (15–180 min). D, RT-PCR analysis of RARß mRNA. RNA was prepared after treating cells with DMSO (Control) or with the indicated concentrations of ACR for 3 h. Similar results were obtained in repeated studies.

We then examined how early the induction of RARß mRNA expression occurs by performing RT-PCR assays in RNA extracts prepared for HepG2 cells at 15, 30, 60, 90, 120, and 180 min after treatment with ACR (20 µM; Fig. 2C). An increase in the RARß band was apparent after 120 min with both 30 and 32 cycles of the PCR when compared with that of untreated cells. We also investigated the dose response effect of ACR on the levels of expression of RARß mRNA (Fig. 2D). HepG2 cells grown in DMEM plus 10% FBS were treated with increasing doses (0.1–100 µM) of ACR, as indicated, and total RNA was isolated at 3 h after addition of the drug. ACR caused an increase in the levels of expression of RARß mRNA in a dose-dependent manner. An increase could be detected with as little as 1 µM and the induction was saturated with about 50 µM ACR (Fig. 2D). Thus, treatment of HepG2 cells with ACR causes a rapid (within 2 h) increase in cellular levels of RARß. This induction increases further at 3 h and persists for at least 24 h. Furthermore, this effect is dose dependent and can be detected with as little as 1 µM ACR. The increase in RARß mRNA apparently leads to a rapid and persistent increase in cellular levels of RARß protein (Fig. 2B). As mentioned above, RARß, when activated by a ligand, can stimulate further expression of RARß (3, 9), ACR can apparently induce a positive feedback loop with respect to RARß synthesis.

ACR Causes a Rapid Increase in the Levels of Expression of p21^CIP1 mRNA and This Induction Occurs via a p53-Independent Mechanism
In the above studies, we found that ACR caused a rapid induction of RARß mRNA and protein within 3 h after addition of the drug to HepG2 cells. Because we reported previously that ACR induces an increase in the protein p21^CIP1 in these cells (8), in the current study, we examined whether ACR affects the levels of expression of p21^CIP1 mRNA under the same conditions in which ACR induced the expression of RARß. HepG2 cells were treated with ACR (20 µM) and RNA samples were prepared at 15, 30, 60, 90, 120, and 180 min and assayed by RT-PCR using primers for p21^CIP1 mRNA (Fig. 3A ). We detected an increase in the intensity of the RARß band within 90 min after the addition of ACR, and the intensity of this band increased further at 180 min (Fig. 3A). To confirm and extend these results, we also did Northern blot analyses for p21^CIP1 mRNA. We found a marked increase in this mRNA within 3 h after the addition of ACR. Further increases were seen at 6, 12, and 24 h. At 48 h, the level declined but still remained relatively high (Fig. 3B). The induction of p21^CIP1 expression can occur via p53-dependent and p53-independent mechanisms (26), and HepG2 cells contain a wild-type p53 gene (27). Therefore, we did parallel time course studies on the effects of treatment of HepG2 cells with ACR on cellular levels of the p21^CIP1 and p53 proteins. Although ACR led to an increase in the level of the p21^CIP1 protein within 3 h and this effect persisted for at least 48 h, during the same time course, there was no significant change in cellular levels of the p53 protein (Fig. 3C). RT-PCR assays for p53 mRNA also indicated no change in cellular levels of this mRNA during the same time course of treatment with ACR (Fig. 3C).

RARß Expression Markedly Stimulates RARE-CAT Activity in the Presence of ACR
Various retinoids appear to exert their antitumor effects through distinct retinoid receptors. Thus, ATRA and 13-cis-retinoic acid appear to act mainly through RARß (28), but 9-cis-RA is a high-affinity ligand and activates RXR (29, 30). However, it is not known with certainty whether ACR mediates its action through a specific nuclear receptor (3). Therefore, to determine whether the ability of ACR to stimulate the transcriptional activity of a RARE is enhanced by specific retinoid receptors, we did transient transfection reporter assays in which a RARE-CAT reporter was transfected into HepG2 cells together with expression vectors of a series of retinoid receptors. We found that RARß expression markedly stimulated CAT activity by about 3-fold after the addition of 30 µM ACR (Fig. 4 ). The expression of RARs and and RXR caused about a 1.5–2-fold stimulation of CAT activity in the presence of ACR (Fig. 4). However, the CAT activity in the presence of ACR was only about 2-fold higher than that in the absence of ACR when cells were cotransfected with either RARs or or RXR. The ACR-induced increases in CAT activity obtained with all four of these expression vectors were statistically significant by Student's t test (each P value < 0.004). These findings, together with our evidence that treatment of HepG2 cells with ACR markedly increases the expression of RARß but not the other retinoid receptors tested (Fig. 2A), suggest that RARß plays an important role in the molecular mechanisms of growth inhibition induced by ACR. They do not, however, exclude the possibility that other nuclear receptors also play a role in this process.

View larger version (16K): [in this window] [in a new window]   Figure 4. Effects of ACR on the transcriptional activity of RARs. The RARE-CAT reporter (2.0 µg) was transfected into HepG2 cells together with control pcDNA3 or RARs , ß, and and RXR expression vectors. The transfected cells were treated for 24 h with 0.1% DMSO (-) or 30 µM ACR (+) in DMEM plus 10% FBS. Extracts were then examined for CAT activity. In these assays, a cytomegalovirus promoter ß-gal plasmid was also cotransfected with the RARE-CAT reporter, and ß-gal activity was measured to normalize the data for transfection efficiency. All assays were done in triplicate. Columns, means; bars, SD.

	Discussion

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We found that treatment of HepG2 cells with ACR caused a rapid (within 2 h) increase in the expression level of RARß mRNA, whereas there were no increases in the levels of expression of RARs and , RXRs and ß, or PPAR mRNA (Fig. 2A). There was also a rapid increase in the levels of expression of the RARß protein (Fig. 2B). These effects of ACR on RARß expression were both time and dose dependent (Fig. 2, C and D). Within 3 h of the addition of ACR to HepG2 cells, there was also a marked and persistent increase in cellular levels of the cell cycle inhibitor protein p21^CIP1 and its related mRNA (Fig. 3). This induction of p21^CIP1 was not associated with cellular levels of p53 mRNA and protein (Fig. 3C), suggesting that ACR induces p21^CIP1 expression by a p53-independent mechanism. Furthermore, we recently reported that the proliferation of HepG2 cells is markedly inhibited by ACR (8). Taken together, these findings suggest that both RARß and p21^CIP1 play critical roles in the molecular mechanisms by which ACR inhibits the growth of human hepatoma cells. Because of the novel open-ring structure of ACR, prior to the present studies, it was not obvious that it inhibits the growth of tumor cells by acting through retinoid receptors. Our finding that, like the physiologic retinoid ATRA (14–17), ACR causes an early and marked induction of RARß and our evidence that in HepG2 cells it induces the transcriptional activity of a RARE-CAT reporter when the cells are cotransfected with RARß expression plasmid (Fig. 4) provide strong evidence that the action of ACR is mediated via retinoid receptors. We have not, however, excluded the possibility that some of the growth inhibitory effects of ACR are mediated via other mechanisms. Another possible mechanism relates to the apparent ability of RARs to inhibit the activity of the transcription factor AP-1 (36). RARß exhibits a strong ATRA-independent inhibition of AP-1 activity, whereas inhibition of AP-1 activity by RARs and is ATRA dependent (37). In HepG2 cells, we found that ACR inhibits both AP-1 and c-Fos promoter activity in a dose-dependent manner and we also found similar effects of ACR in a human squamous cell carcinoma cell line (unpublished data). Thus, the growth inhibitory effects by ACR might also occur through inhibition of AP-1 and/or c-Fos activity.

Several studies demonstrate that exogenous expression of RARß increases the growth inhibition exerted by ATRA on cervical carcinoma (38, 39), renal carcinoma (40), and breast carcinoma cells (41–43). In a recent study, we found that Huh7 human hepatoma cells are more sensitive to growth inhibition by ACR than HepG2 cells (8), and in unpublished studies, we found that the former cells express higher levels of the RARß protein (data not shown). Therefore, the level of expression of RARß in hepatoma cells may influence their sensitivity to the growth inhibitory effects of ACR. Other studies have found that increased expression of RAR but not RARß in the SqCC/Y1 human SCC cell line increased the sensitivity of these cells to growth inhibition by ATRA and 9-cis-RA (34, 44). In addition, appreciable levels of RARß are expressed in some retinoic acid-resistant tumor cell lines (45). Therefore, the sensitivity of specific hepatoma and other types of tumor cells to growth inhibition by ACR may be influenced by factors other than basal or inducible levels of RARß.

The promoter region of the p21^CIP1 gene contains a RARE to which both RARs and RXRs can bind (36). Through this element, retinoid receptors can activate the transcription of the p21^CIP1 gene (23). The p21^CIP1 promoter sequence from residues –1212 to –1194 defines a functional RARE that is required to mediate the induction by ATRA of p21^CIP1 transcription (23). Several inducers of myeloid cell differentiation also up-regulate p21^CIP1 expression (24, 46). These include 12-O-tetradecanoyl phorbol-13-acetate, okadaic acid, sodium butyrate, DMSO, 1,25-dihydroxyvitamin D3, and retinoids. Thus, the p21^CIP1 promoter contains multiple response elements involved in cell cycle arrest, growth inhibition, and/or differentiation. This may explain why we found that ACR causes rapid induction of p21^CIP1 expression in HepG2 cells (Fig. 3). Presumably, this occurs through the RARE in the promoter region of p21^CIP1 and is mediated at least in part by RARß. This speculation is consistent with evidence that treatment of HL-60 human leukemia cells with ATRA also causes rapid induction of p21^CIP1 mRNA (24, 46). In addition, a novel synthetic retinoid 6-[3-(1-adamantyl)-4-hydroxyphenyl]-2-naphthalene and the conventional retinoid 9-cis-RA caused a rapid and dramatic increase in the levels of p21^CIP1 mRNA and protein in human MCF-7 and MDA-MB-231 breast carcinoma and TMK-1 gastric carcinoma cell lines (47, 48). Our finding that the induction of p21^CIP1 by ACR in HepG2 cells occurs via a p53-independent mechanism (Fig. 3C), although these cells carry a wild-type p53 gene (27), is consistent with evidence that induction of p21^CIP1 by ATRA in HL-60 cells (24, 46) and induction by a novel synthetic retinoid 6-[3-(1-adamantyl)-4-hydroxyphenyl]-2-naphthalene of G₁ arrest and apoptosis in the MDA-MB-231 and MCF-7 cell lines (48) also occur via p53-independent mechanisms.

In our previous studies, we found that treatment of HepG2 cells with ACR caused a rapid (within 3 h) decrease in cellular levels of the hyperphosphorylated (inactivated) form of the retinoblastoma protein (8). Increased expression of p21^CIP1 often occurs during differentiation (24). In addition, decreased phosphorylation of retinoblastoma protein and cell cycle arrest in G₁ also occur during the induction of differentiation in HL-60 cells (49). Therefore, it is of interest that previous studies found that treatment of Huh7, Hep3B, and the PLC/PRF/5 human hepatoma cell lines with ACR induced expression of albumin mRNA, a putative marker of differentiation in these cells (35), although ATRA repressed albumin expression in these cells (50). More detailed studies are required to further characterize possible effects of ACR on the differentiation of hepatoma cells.

The present studies provide evidence that the growth inhibitory effects of ACR in human hepatoma cells are mediated at least in part via retinoid receptors, especially RARß, and the RARE present in the p21^CIP1 gene. It seems likely that RAR elements in other retinoid-responsive genes also play a role in this process. Despite its unusual chemical structure, the molecular mechanisms of action of ACR resemble those of several retinoids. A serious limitation in the clinical use of ATRA and other retinoids in cancer chemoprevention and therapy is their adverse effects, particularly with prolonged administration. These can include dryness of the skin and lips, skin rash, nasal congestion, and, in some cases receiving high doses, a severe "retinoic acid syndrome" (51, 52). On the other hand, thus far, clinical studies with ACR have not revealed the adverse effects seen with conventional retinoids (4, 5). The reasons why ACR appears to be better tolerated are not known, and this aspect warrants further study.

	Footnotes

 
Grant support: Supported by awards from the National Foundation for Cancer Research and the T. J. Martell Foundation (I. B. Weinstein), and a grant from the Ministry of Education, Culture, Sports, Science and Technology of Japan (M. Suzui).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Received 7/21/03; revised 12/ 2/03; accepted 12/ 4/03.

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