Rb2/p130 and protein phosphatase 2A: key mediators of ovarian carcinoma cell growth suppression by all-trans retinoic acid.

Despite a number of attempts to improve treatment of ovarian cancer, it remains the most common cause of death from gynecological cancers. Thus, it is very important to identify more effective drugs for treatment and prevention of ovarian cancer. All-trans-retinoic acid (ATRA) has been shown to arrest the growth of ovarian carcinoma cells in G0/G1 and to significantly elevate levels of Rb2/p130 protein, a member of the retinoblastoma family of tumor suppressors. As ATRA treatment leads to a significant increase in the amount of Rb2/p130 protein but not mRNA, the elevated levels of Rb2/p130 protein is likely the result of increased stability. In studies to elucidate the mechanism by which ATRA alters Rb2/p130 stability in ovarian cancer cells, it was determined that PP2A, a serine/threonine phosphatase, binds and dephosphorylates Rb2/p130. Dephosphorylated Rb2/p130 exhibits decreased ubiquitination and thus is not degraded by the proteasome. The sites at which PP2A catalytic subunit (PP2Ac) interacts with Rb2/p130 have been localized to the NLS in the C-terminus of Rb2/p130. These sites are also involved in the interaction of Rb/p130 with importin beta and importin alpha, members of the nuclear transport machinery. It is known that importin alpha recognizes a NLS on a target protein and importin beta binds the nuclear pore complex. Moreover, it has been shown that the binding of importin alpha to NLS significantly decreases with phosphorylation of NLS. In ATRA-treated ovarian carcinoma cells, PP2A binds to Rb2/p130 and dephosphorylates the NLS of Rb2/p130 leading to the interaction of importin alpha with Rb2/p130. Importin beta then binds to the importin alpha-Rb2/p130 complex, leading to the translocation of the Rb2/p130 to the nucleus where it acts to arrest ovarian cancer cells in G1 and suppress proliferation.

Cross-resistance to the synthetic retinoid CD437 in a paclitaxel-resistant human ovarian carcinoma cell line is independent of the overexpression of retinoic acid receptor-gamma.

Treatment of ovarian carcinomas with the antimitotic antitumor drug paclitaxel is highly efficacious. However, development of drug resistance presents a major obstacle. The common cellular phenotypes associated with paclitaxel resistance are an increased expression of the drug transport protein P-glycoprotein (P-gp), an alteration in the levels of beta-tubulin isotypes, and/or changes in the drug binding affinity of the microtubules. We established two paclitaxel-resistant human ovarian carcinoma cell lines. The 2008/17/4 cells exhibited a "classic" multidrug-resistant phenotype (overexpression of P-gp associated with cross-resistance to natural product drugs), whereas the 2008/13/4 cells were an atypical multidrug-resistant subline (no overexpression of P-gp). In addition to being paclitaxel resistant (250-fold), the 2008/13/4 cells were also cross-resistant to etoposide (39-fold) and vincristine (460-fold). To identify the alterations in the gene expression profile associated with the development of atypical paclitaxel resistance, we used the Clontech Atlas Human Cancer cDNA Microarray (spotted with 588 genes). The expression of retinoic acid receptor (RAR)-gamma was significantly higher in the paclitaxel-resistant (2008/13/4 and 2008/17/4) cells than in the parental (2008) cells. Northern blotting analysis demonstrated that the expression of RAR-gamma was 7-fold higher in the 2008/13/4 and 2008/17/4 cells than in the 2008 cells, whereas the expression of RAR-alpha and RAR-beta was not observed in any cell line. Whereas the 2008, 2008/13/4, and 2008/17/4 cells were found to resist the antiproliferative effects of all-trans-retinoic acid, the paclitaxel-resistant cells were 6- to 7-fold cross-resistant to the antiproliferative effects of CD437 (a synthetic RAR-gamma-selective agonist; 6-[-(1-admantyl)-4-hydroxyphenyl]-2-naphthalenecarboxylic acid) compared with the sensitivity of the parental cells. To further understand the association of paclitaxel and CD437 resistance with the observed RAR-gamma overexpression, we transfected the 2008 cells with a full-length RAR-gamma cDNA construct. Two transfectants with increased expression of the RAR-gamma mRNA and protein were isolated and subjected to growth inhibition assays in the presence of various concentrations of paclitaxel, etoposide, vincristine, and CD437. The sensitivity of the 2008 transfected clones (displaying increased expression of RAR-gamma) to the cytotoxic effects of paclitaxel, etoposide, vincristine, and CD437 was similar to that observed in the parental 2008 cells. These results suggest that the overexpression of RAR-gamma (observed in the 2008/13/4 and 2008/17/4 cells) by itself is not capable of inducing paclitaxel and CD437 resistance (or resistance to etoposide and vincristine).

Transcriptional regulation of c-Jun expression during late G1/S in normal human cells is lost in human tumor cells.

Previous results from our laboratory have identified a second peak in steady state levels of c-jun mRNA (in addition to the immediate early induction) which occurs at the G1/S border in WI-38 normal human diploid fibroblasts. The present studies were undertaken in an attempt to determine (1) the molecular mechanism responsible for the expression of c-jun in late G1/S, (2) the relationship between this second peak of c-jun mRNA expression and the induction of DNA synthesis and (3) whether this cell cycle specific c-jun expression is deregulated in transformed cells. Our results show that the second peak in steady state levels of c-jun mRNA is the result of new transcription during late G1 and not altered stability of the c-jun mRNA transcribed during G1. We also show that this second peak of expression still occurs even when DNA synthesis is inhibited by either hydroxyurea or aphidicolin. Thus, the second peak precedes and is independent of DNA synthesis. Finally, we find that while two other normal human fibroblast cell lines exhibit a second peak of c-jun mRNA during late G1/S, c-jun expression is not cell cycle-regulated but rather is constitutively expressed in a number of distinct transformed cell lines. Since events occurring throughout G1 are known to regulate cell growth, our results suggest that the extent of regulation of c-jun expression during G1 may affect molecular events which ultimately lead to altered growth control as a result of cellular transformation.

Modulation of retinoic acid receptor function alters the growth inhibitory response of oral SCC cells to retinoids.

Retinoids have been shown to inhibit the growth of many human tumor cells including breast, ovarian and squamous cell carcinoma (SCC). While the exact mechanism of retinoid mediated growth suppression is not known, a role for the retinoic acid receptors (RARs) and retinoid X receptors (RXRs) has been established in both the breast and ovarian tumor cell models. We set out to determine if modulation of RAR/RXR function would alter the retinoid sensitivity of oral SCC cells. We found that the growth of SCC cells was significantly inhibited by treatment with either all-trans-retinoic acid (trans-RA) or the synthetic, conformationally restricted RARgamma selective retinoids MM11254 and MM11389. In order to demonstrate a role for RAR/RXR function in this process, stable oral SCC cell clones constitutively overexpressing the dominant negative mutant RARbeta2 (R269Q) were prepared and shown to exhibit reduced RAR/RXR transcriptional transactivation activity. We found that oral SCC cells exhibiting reduced RAR/RXR function became resistant to growth inhibition by all-trans-RA, MM11254 and MM11389. Likewise, treatment of oral SCC cells with the RARgamma antagonist MM11253 was found to block the ability of MM11254 and MM11389 to inhibit SCC cell growth. Thus, modulation of RAR function through the use of RAR-gamma selective agonists, an RAR-gamma selective antagonist or a pan-RAR dominant negative mutant significantly alters the growth inhibitory response of oral SCC cells to retinoids.

Overexpression of Mxi1 inhibits the induction of the human ornithine decarboxylase gene by the Myc/Max protein complex.

We have previously shown that the Myc/Max protein complex plays a role in the growth-associated expression of the human ornithine decarboxylase gene. Mxi1 and Mad, novel Max-associated proteins have been identified and shown to form heterodimers with Max which bind efficiently to the Myc/Max consensus recognition sequence, CACGTG, in vitro. However, formation of Max/Mxi1 or Max/Mad heterodimers results in a reduction in Myc/Max dependent transcriptional activation of reporter plasmid constructs containing the consensus element. In light of the evidence that ODC is transcriptionally regulated in vitro and in vivo by the Myc/Max protein complex and the potential role of Mxi1 and Mad as antagonists of Myc transactivation activity, we set out to determine if one of these Max associated proteins, Mxi1, could affect the regulation of ODC expression by Myc/Max and if this regulation was correlated to growth status. Our results show that overexpression of Mxi1 does in fact inhibit ODC gene expression in a dose-dependent manner both in vivo and in vitro. In addition, evidence is presented which shows that levels of Mxi1 are up-regulated during long term quiescence and down-regulated following growth stimulation by serum. These results suggest that alterations in the levels of Max-associated proteins such as Mxi1 can modulate critical levels of functional Myc/Max protein complexes. This can alter transcriptional transactivation of Myc-regulated targets and as a consequence affect levels of genes essential for initiation and/or maintenance of growth.

A potential role for c-jun in cell cycle progression through late G1 and S.

When the level of c-jun mRNA was analyzed in WI-38 human fibroblasts exciting short- and long-term quiescence, two peaks of c-jun mRNA accumulation were found. The first occurred one hour after stimulation and lasted three to five hours, whereas the second occurred at the G1/S border and was coupled to the time of entry to S phase rather than to the time of stimulation. The early peak is well documented and in agreement with the proposed role of c-Jun/AP-1 in mediating cellular responses to receptor-generated signals. The later peak, however, has not been previously reported. Additional follow-up studies showed that late G1/S expression was not solely a phenomenon of cells existing a quiescent state, nor was it restricted only to human cells. Gel retardation studies confirmed that there is AP-1 specific DNA binding activity in nuclear extracts isolated in late G1 and S phase, and that this AP-1 binding activity is due to the presence of Jun protein. An anti-Fos antibody was able to significantly decrease AB-1 binding activity in early G1 extracts, but had no effect on extracts isolated in late G1 and S phase, indicating that the complexes observed in late G1 and S phase are clearly different from those seen in early G1. These studies are among the first to suggest a functional dissociation of c-Jun from c-Fos. Our results identify a new, previously unreported role for c-Jun/AP-1 in regulation of cell cycle progression and mammalian cell growth.

Critical role of both retinoid nuclear receptors and retinoid-X-receptors in mediating growth inhibition of ovarian cancer cells by all-trans retinoic acid.

Retinoids have been shown to inhibit the growth of a number of human tumor cells, including several ovarian adenocarcinoma cell lines. All-trans retinoic acid (RA) is an effective growth suppressor of CA-OV3 cells but not SK-OV3 cells. Since the effects of RA are known to be mediated via the nuclear receptors (RARs and RXRs), we initially compared levels of the various RARs and RXRs in the CA-OV3 and SK-OV3 cell lines. The RA resistant SK-OV3 cells expressed reduced levels of RAR-alpha and RXR-alpha. Furthermore, induction of RAR-alpha by RA was impaired in the RA resistant SK-OV3 cells as was RARE binding and RARE-dependent transcriptional activity. These results suggested that changes in the amounts and/or activity of RARs and/or RXR-alpha could determine the growth response of ovarian tumor cells to RA. This was confirmed by modulating the levels of RARs and RXR-alpha in the SK-OV3 cells using the LacSwitch inducible expression system. Stably transfected clones of RA resistant SK-OV3 cells exhibited a significant inhibition of growth by RA treatment when RAR-alpha was induced. Overexpression of both RAR-alpha and RXR-alpha resulted in a level of growth inhibition nearly equal to that exhibited by the RA sensitive CA-OV3 cell line. Similar results were obtained when a combination of RXR-alpha and either RAR-beta or RAR-gamma was overexpressed in SK-OV3 cells. Our results show that the nuclear receptors and RXR-alpha play a critical role in mediating growth suppression by RA in ovarian cancer cells.

Overexpression of both RAR and RXR restores AP-1 repression in ovarian adenocarcinoma cells resistant to retinoic acid-dependent growth inhibition.

Retinoids including retinoic acid (RA) have been demonstrated to be effective growth inhibitors of a number of human cancer cell lines including ovarian adenocarcinoma cells. To begin to determine the mechanism of action by which RA inhibits the growth of ovarian carcinoma cells, we have examined AP-1 activity in two representative cell lines: CaOV-3 a RA-sensitive cell line and SK-OV-3 a RA-resistant cell line. AP-1 activity was found to be inhibited by 50% upon RA treatment of the RA-sensitive cells while there was no change in AP-1 activity following RA treatment of the RA-resistant cells. Maximal inhibition of AP-1 activity could be achieved in the RA-resistant SK-OV-3 cells by overexpression of any one of the three retinoic acid receptor (RAR) subtypes in conjunction with retinoid X receptor (RXR) alpha. This inhibition of AP-1 activity was nearly comparable to that of the RA-sensitive cells. A similar change in AP-1 complex formation in vitro has also been observed. These results suggest that one mechanism by which RA inhibits growth of RA-sensitive ovarian carcinoma cells is by repressing AP-1 activity. Moreover, in the RA-resistant cells the RAR/RXR signalling pathway leading to inhibition of AP-1 activity is impaired however overexpression of one of the RAR subtypes along with RXR alpha is sufficient to restore this pathway.

Cell cycle genes as targets of retinoid induced ovarian tumor cell growth suppression.

We have examined the effect of all-trans-retinoic acid (RA) on cell cycle gene expression in RA sensitive CA-OV3 and RA resistant SK-OV3 ovarian carcinoma cell lines. Gene expression was analysed by multiprobe RNAse protection, Western blotting and in vitro kinase assays. No differences were observed between RA sensitive and RA resistant ovarian carcinoma cells in the levels of expression of many cell cycle genes including cyclin A, B and E, cdk 2,4 and 6, E2F-1, E2F-2, E2F-3, E2F-4, E2F-5, DP-1 and DP-2. However, RA sensitive CA-OV3 cells expressed higher levels of p53, p27, p21, and p16 compared to RA resistant SK-OV3 cells. In addition, RA treatment of CA-OV3 cells resulted in a significant decrease in hyperphosphorylated RB and RB-2/p130 and corresponding significant increases in the levels of hypophosphorylated and/or partially phosphorylated RB-2/p130 protein and hypophosphorylated RB. Also, RA treatment increased expression of the cdk inhibitor p27 and decreased activity of cdk 2, cdk 4 and cdk 6. Finally, amounts of p27-cyclin E and RB-2/p130-E2F4 complexes were found to increase in CA-OV3 cells growth arrested by RA. These results suggest that the pocket protein pathways are critical targets for retinoid suppression of ovarian carcinoma cell growth.

Sequencing of the primary adhesion domain of bovine von Willebrand factor.

A cDNA library, constructed from bovine heart endothelial cell poly(A)+ RNA, was screened using a BstXI fragment of human von Willebrand and factor (vWF) cDNA as a probe. This probe codes for the major adhesion domain of vWF that includes the GPIb, collagen and heparin binding domains. Of the ten positive clones obtained, a clone that spanned the region of interest was sequenced by the dideoxynucleotide method yielding a sequence of 1550 bp. This region of the bovine cDNA codes for amino acids corresponding to #262 to #777 in human vWF and encompasses the entire pro adhesion domain. Both the nucleotide sequence and the deduced amino acid sequence are 82% homologous to those of human vWF. Cysteine residues #471, 474, 509 and 695, which form intrachain bonds in human vWF, are also present in the bovine vWF sequence.

A sustained elevation in retinoic acid receptor-beta 2 mRNA and protein occurs during retinoic acid-induced fetal dysmorphogenesis.

We have previously shown that oral treatment of pregnant mice with all-trans retinoic acid (RA) at doses which cause 100% fetal dysmorphogenesis results in a rapid elevation in the mRNA of one specific isoform of the RA receptor-beta, RAR-beta 2, in susceptible embryonic regions. To further investigate the involvement of RAR-beta 2 mRNA in teratogenesis, we have examined its expression in mouse embryos exposed to marginal/nonteratogenic and teratogenic dosing regimens of both 13-cis RA and all-trans RA. We have found that the mere elevation in embryonic RAR-beta 2 mRNA levels and free retinoid levels is not sufficient to result in dysmorphogenesis. Rather, retinoid-induced dysmorphogenesis of embryos appears to occur only when RAR-beta 2 mRNA and unbound retinoid levels remain elevated for at least 6-9 h following retinoid treatment resulting in a significant and prolonged elevation in RAR-beta protein levels.

Modulation of limb bud chondrogenesis by retinoic acid and retinoic acid receptors.

An excess of retinoic acid (RA) in the mouse embryo in utero produces hypochondrogenesis and severe limb bone deformities. Since one of the RA receptors--RAR-beta 2, is specifically induced in the limb bud cells upon treatment of embryos with teratogenic doses of RA, we investigated if this receptor played a role in teratogenesis by regulating the process of chondrogenesis. In micromass cultures of mouse limb bud mesenchymal cells, we found that a downregulation of RAR-beta 2 as well as several other RAR isoforms by supplementation of the culture medium with specific oligodeoxynucleotides stimulated chondrogenesis: cartilage nodule number, sulfated proteoglycans, and synthesis of collagen type IIB were all enhanced in a dose-dependent manner. However, only the antisense RAR-beta 2 probe efficiently prevented the strong inhibitory effects of exogenous RA on chondrogenesis in these cells. The data suggest that the RAR-RA complexes play a role in position-dependent patterning of the limb skeleton in normal development and that, in particular, RAR-beta 2 serves to prevent the mesenchymal cells from expressing their chondrogenic bias. Our results further strengthen the argument that RA-dependent elevation in RAR-beta 2 levels plays a unique role in RA-induced teratogenesis.

Regulation of retinol-binding protein metabolism by glucocorticoid hormones in cultured H4II EC3 liver cells.

Studies were conducted to explore the effects of glucocorticoid hormones on the regulation of the metabolism of retinol-binding protein (RBP) by H4II EC4 rat hepatoma cells in culture. Cortisol, corticosterone, and the synthetic glucocorticoid analog dexamethasone all induced a 2- to 3-fold increase in accumulation of RBP. Half-maximal stimulation occurred at concentrations of dexamethasone in the range of 1-5 nM. Progesterone in the concentration range of 1-10 microM, inhibited the stimulatory effect of dexamethasone. Progesterone alone in this concentration range had no effect on RBP metabolism. By analogy with the studies of others, these observations with progesterone suggest that glucocorticoid receptors are involved in the effect of dexamethasone on RBP. As previously reported, RBP accumulated in the hepatoma cells when they were incubated in a medium free of serum and of vitamin A. The addition of retinol over a range from 3.5 nM to 3.5 microM stimulated a dose-dependent secretion of RBP from the cells into the medium. In longer experiments, retinol also stimulated the accumulation of RBP. Neither dexamethasone nor retinol had an effect on the accumulation or the cell to medium distribution of rat serum albumin or prealbumin at concentrations which were maximally stimulatory for RBP. When studied over a wide range of concentrations, retinol and dexamethasone incubated together produced approximately additive increases in the accumulation of RBP. Dexamethasone, moreover, did not affect the retinol-induced secretion of RBP. Thus, retinol and dexamethasone appear to function via different and independent mechanisms to regulate the metabolism of RBP by the liver cell.

Transthyretin: a choroid plexus-specific transport protein in human brain. The 1986 S. Weir Mitchell award.

Plasma transthyretin (TTR, formerly called prealbumin) is a 55-kd protein that participates in the plasma transport of both thyroxine and retinol (vitamin A). TTR concentrations are disproportionately high in human ventricular CSF, suggesting that TTR is either selectively transported across or synthesized de novo within the blood-CSF barrier. To address this question, we adopted a molecular genetic approach; after isolating a cDNA clone encoding human TTR, we previously demonstrated specific TTR messenger RNA (mRNA) synthesis in rat choroid plexus. We have now extended these investigations to the human brain. Northern analysis of postmortem brain homogenates revealed abundant TTR mRNA in choroid plexus, but not in cerebellum or cerebral cortex. Choroid plexus mRNA was readily translated into TTR preprotein in an in vitro translation system. An immunocytochemical survey of human postmortem brain sections revealed the presence of TTR protein specifically and uniquely in the cytoplasm of choroid plexus epithelial cells; these results were corroborated at the mRNA level by an extensive survey of whole rat-brain sections by in situ hybridization. Therefore, within the mammalian CNS, TTR is the first known protein synthesized solely by the choroid plexus, suggesting a special role for TTR in the brain or CSF. Whether this function differs from its established plasma transport functions is presently unknown.

Use of antisense oligomers to study the role of c-jun in G1 progression.

In actively proliferating Swiss 3T3 fibroblasts, expression of the protooncogene c-jun is maximally induced early in G1, immediately after completion of mitosis. Within 2 hours, c-jun mRNA levels drop to a basal amount that is approximately 30% of the maximum. This is maintained throughout the remainder of G1. To access the functional implications of this pattern of c-jun expression, antisense oligomers specific to c-jun were added to either actively proliferating or synchronized Swiss 3T3 cells, and their ability to inhibit DNA synthesis and division was determined. Our results show that if Swiss 3T3 cells are treated with anti-c-jun while actively growing or at any time during G1 after completion of mitosis, they exhibit a reduced ability to enter S-phase and subsequently divide. These results demonstrate that the regulation of G1 progression following mitosis depends on the expression and function of the protooncogene c-jun.

Effect of all-trans retinoic acid on telomerase activity in ovarian cancer cells.

Vitamin A is an essential nutrient important for growth, vision, embryonic development, immune response and reproduction. Various retinoids have been shown to be effective chemotherapeutic and chemopreventive agents for a number of human cancers. Telomeres are nucleoprotein structures found at the end of chromosomes. During cellular division, the telomeres in normal cells shorten progressively and thus, function as a "molecular clock". Telomerase is a ribonucleoprotein complex that extends and maintains telomeres. Activation of telomerase is required for cells to overcome proliferative crisis. Telomerase activation is observed in 90% of human cancers, but not in normal somatic cells. We examined the role of telomerase in mediating the growth suppression of ovarian carcinoma cells by all-trans-retinoic acid (ATRA). Using a number of cell lines with varying levels of growth sensitivity to ATRA, we found that cells that exhibit ATRA-dependant suppression of growth also contained significantly reduced telomerase activity. We also observed a reduction in expression of the telomerase components, hTERT and hTR in ATRA treated ovarian carcinoma cells. Our results suggest that one mechanism by which ATRA acid inhibits cancer cell growth is by suppressing telomerase activity, thereby pushing cells to proliferative crisis.

Novel retinoic acid metabolism blocking agents have potent inhibitory activities on human breast cancer cells and tumour growth.

Antitumour effects of retinoids are attributed to their influence on cell proliferation, differentiation, apoptosis and angiogenesis. In our effort to develop useful agents for breast cancer therapy, we evaluated the effects of four representative retinoic acid metabolism blocking agents (RAMBAs, VN/14-1, VN/50-1, VN/66-1 and VN/69-1) on growth inhibition of oestrogen receptor positive (ER +ve, MCF-7 and T-47D) and oestrogen receptor negative (ER -ve, MDA-MB-231) human breast cancer cells. Additionally, we investigated the biological effects/molecular mechanism(s) underlying their growth inhibitory properties as well as their antitumour efficacies against MCF-7 and MCF-7Ca tumour xenografts in nude mice. We also assessed the effect of combining VN/14-1 and all-trans-retinoic acid (ATRA) on MCF-7 tumour xenografts. The ER +ve cell lines were more sensitive (IC(50) values between 3.0 and 609 nM) to the RAMBAs than the ER -ve MDA-MB-231 cell line (IC(50)=5.6-24.0 microM). Retinoic acid metabolism blocking agents induced cell differentiation as determined by increased expression of cytokeratin 8/18 and oestrogen receptor-alpha (ER-alpha). Similar to ATRA, they also induced apoptosis via activation of caspase 9. Cell cycle analysis indicated that RAMBAs arrested cells in the G1 and G2/M phases and caused significant downregulation (>80%) of cyclin D1 protein. In vivo, the growth of MCF-7 mammary tumours was dose-dependently and significantly inhibited (92.6%, P<0.0005) by VN/14-1. The combination of VN/14-1 and ATRA also inhibited MCF-7 breast tumour growth in vivo (up to 120%) as compared with single agents (P<0.025). VN/14-1 was also very effective in preventing the formation of MCF-7Ca tumours and it significantly inhibited the growth of established MCF-7Ca tumours, being as effective as the clinically used aromatase inhibitors, anastrozole and letrozole. Decrease in cyclin D1 and upregulation of cytokeratins, Bad and Bax with VN/14-1 may be responsible for the efficacy of this compound in inhibiting breast cancer cell growth in vitro and in vivo. Our results suggest that our RAMBAs, especially VN/14-1 may be useful novel therapy for breast cancer.

Retinoids as teratogens.

Vitamin A is a necessary nutrient in the diet. However, excessive doses of retinoids by pregnant women result in teratogenesis. In this chapter, we initially discuss the occurrence and characteristics of fetal malformations associated with maternal ingestion of natural and synthetic retinoids in both experimental animals and humans. We then turn to an examination of the pharmacology of teratogenic retinoids, focusing on structure-function relationships and pharmacokinetics. Finally, we review the current literature on the molecular mechanism of action of teratogenic doses of retinoids and the role of the retinoic acid receptors and other target genes in this process.

Tyrosine protein kinase expression in long-term quiescent WI-38 cells following growth factor simulation.

We have used the WI-38 cell long-term quiescent model system to study the regulation of cell cycle progression at the molecular level. By modulating the length of time that WI-38 cells are density arrested, it is possible to proportionately alter the length of the prereplicative or G-1 phase which the cell traverses after growth factor stimulation in preparation for entry into DNA synthesis. Stimulation of long- and short-term density arrested WI-38 cells with different growth factors or higher concentrations of individual growth factors does not alter the time required by long-term cells to enter S after stimulation. However, the time during the prereplicative period for which these growth factors are needed is different. Long-term quiescent WI-38 cells require EGF to traverse the G-0/G-1 border but do not need and apparently cannot respond to IGF-1 during the first 10 h after EGF stimulation, the length of the prolongation of the prereplicative phase. This suggests that EGF stimulation of long-term quiescent WI-38 cells initiates a series of molecular events which make these cells "competent" to respond to the "progression" growth factor, IGF-1. In light of the well-established role of protein tyrosine kinases in signal transduction, we set out to identify, clone, and analyze the expression of receptor and non-receptor tyrosine kinases which potentially could play a role during the prolongation of the prereplicative phase in making the long-term quiescent WI-38 cells competent to respond to IGF-1. We obtained 49 clones representing 11 different receptor and non-receptor type protein tyrosine kinases. Analysis of expression of these clones revealed a variety of different patterns of expression. However, the most striking pattern was exhibited by IGF-1 receptor. Our results suggest that induction of IGF-1 receptor mRNA by EGF may be an important event in the establishment of competence by EGF in long-term density arrested WI-38 cells.