Cancer Chemopreventive Retinoids: Validation and Analysis of in Vivo and in Vitro Bioassay Results

Abstract

Several natural and synthetic retinoids (vitamin-A derived analogies) were examined for their potential anti-cancer activity in both in vivo animal models and a novel in vitro human keratinocyte clonal growth bioassay system. The natural retinoids included all-trans-retinoic (RA), 13-cis-retinoic acid, 4-oxoretinoic acid, and retinol. Among the synthetic retinoids tested were all trans N-(4-hydroxy(phenyl)retinamide, 3-substituted oxoretinoic acids, and 13 cis-N-ethylretinamide. The animal models employed were: 1) vitamin A-deficient hamster tracheal organ assay (HTOC); 2) the benzo(α)pyrene-induced squamous metaplasia in a hamster tracheal organ system (BP-HTOC); 3) the mouse skin tumor promoter (TPA)-induced ornithine decarboxylase enzyme assay(ODC); 4) the mouse skin papilloma (MPA) assay; and 5) a novel retinoid bioassay in which retinoids display IC50 values to inhibit clonal growth of NHK. All-trans-RA, 4-oxoretinoic acid and retinol were consistently more active than any of the synthetic derivatives in all bioassays tested. A statistical model was developed and significant positive correlations were found between: 1) ED50 values in the HTOC system and reduction in TPA-induced ODC enzyme activity; 2) tumors per animal in the MPA bioassay and suppression of TPA-induced ODC activity; and 3) a positive correlation between suppression of tumors per animal in the MPA assay, and retinoid inhibition of keratinocyte clonal growth. Test retinoids, were tested for their capacity to inhibit the clonal growth of a squamous carcinoma cell line (SCC-25), which were found to be 2 - 3 logs less sensitive for each tested retinoid than the corresponding activity against NHK cells. Antineoplastic retinoid drugs were reviewed.

Share and Cite:

Wille, J. , Park, J. and Shealy, Y. (2016) Cancer Chemopreventive Retinoids: Validation and Analysis of in Vivo and in Vitro Bioassay Results. Journal of Cancer Therapy, 7, 1008-1033. doi: 10.4236/jct.2016.713098.

1. Introduction

Carcinogenesis is a multistep process that alters normal phenotype of cells into malignant counterparts, which acquire the ability to invade and metastasize, resulting in clinically frank cancers. Over the last several decades, significant progress has been made in our understanding of the physiological, genetic, environmental, and biochemical basis of cancer etiology [1] . Retinoids are a class of vitamin A analogs which display remarkable ability to promote the growth and differentiation of a variety of mammalian epithelial tissue [2] . Importantly, retinoids are highly active in the suppression of experimental carcinogenesis in both in vivo and in vitro animal models [3] [4] . Furthermore, with the finding that retinoids can arrest or reverse the transformed phenotype of cancer cell in in vitro experimental carcinogenesis [3] , the promise of clinical remission of some cancers has seen some success particularly with the treatment of acute promelocytic leukemia (AML) [5] . Nevertheless, the problem of retinoid resistance [6] [7] has prompted the need to search for new retinoids that might overcome both the problem of toxicity and retinoid resistance. Derivatives of vitamin A, retinoids, have reported activity in treating specific premalignant lesions, and in reducing the incidence of second primary tumors in patients with prior head and neck, lung and liver cancers, but it remains to be proven that retinoids can prevent primary cancers at these sites [8] . With the discovery that retinoids activate nuclear retinoid receptors (RARα, RARβ, and RARγ, and RXR) which form heterodimers that act as transcription activators of specific target genes by modulating gene expression programs, retinoids and rexinoids have been extensively tested in many preclinical studies and for the treatment of malignancies as reviewed elsewhere [9] [10] [11] [12] . In the past, the development of new retinoids has been based primarily on existing data that indicate that substituent modifications could be made at either the nonpolar cyclohexanol ring or at the opposite free carbonyl terminus or at both ends of the vitamin A molecule [13] . Many of these have been found to have potential cancer chemopreventive activity [14] [15] . In this regard, it was reported that the bifunctional retinoids are ineffective as they do not have any binding affinity to the cytoplasmic retinoid receptor CRBPs; similarly, the class of retinoyl-amino acids has been reported to possess activity in the hamster tracheal organ culture (HTOC) bioassay [15] [16] . Close examination of these data, however, indicates that retinoyl-amino acids have anywhere from 3 - 5 logs less activity than t-RA. In support of these data, neither the bifunctional retinamides nor the retinoyl-amino acid binds to CRBP [17] . Studies on a series of conformationally-restricted retinoids showed biological activity in both the HTOC bioassay and the retinoid suppression of tumor promoter-induced ornithine decarboxylase (ODC) enzyme bioassays [18] [19] [20] . The focus of our study was to evaluate the potential chemo-preventive activity of selectively natural and synthetic retinoids using several different biological assays and to determine the validity of the methods by investigating whether significant positive linear correlations existed between two or more of the bioassay data. Earlier, we reported results showing that retinoids were active in reversing keratinization in the standard vitamin A-deficient HTOC correlated with the biological activity of retinoids active in reversing keratinization in the HTOC-benzo(α)pyrene-induced squamous metaplasia [16] . We here, and others have shown a correlation between rank order of retinoid to suppress tumor promoter-induced ornithine decarboxylase (ODC) enzyme bioassay [21] [22] and retinoid rank order of potencies in the mouse skin two-stage carcinogenesis (MPA) bioassay. Here, we also report the development of a novel bioassay that employs a rapid and effective in vitro keratinocyte clonal growth method to yield a sensitive rank order of the retinoid potencies with both the ODC and the MPA bioassays.

2. Materials and Methods

Chemicals: RA was purchased from Sigma Chemical Co., St. Louis, MO. All other retinoids were prepared and supplied by Dr. Y. Fulmer Shealy of Southern Research Institute, Birmingham, AL.

Animals: Female CD-1 mice were purchased from commercial source (Charles River) and housed and fed as previously reported [16] . Syrian Golden hamsters were purchased from Charles River and housed and feed as previously reported [16] .

Bioassay methods: 1) ODC Assay: retinoid-mediated suppression of tumor promoter- induced ornithine decarboxylase (ODC) enzyme activity in mouse skin epidermal extracts: Briefly, a group of 3 to 4 CD-1 mice were shaved and their backs painted with 0.2 mL of acetone (control) or 0.2 mL of 17 nm of 13-tetradecanoyl-phorbol-12-acetate (TPA). The area of treated skin was excised and epidermal extracts prepared and their ODC activity was determined by measuring the production of 14C-CO2 formed by conversion of radiolabelled putrescine to ornithine as previously described [21] [22] . All ODC assays were performed on mice sacrificed 5 hours after TPA treatment. The protocol developed for testing retinoids always included two TPA only treatment groups, one at the start of the assay and one at the end of the assay to ensure that the inhibitory effect of the unknown test retinoid on ODC levels was bracketed in the window of maximal TPA induction. All test retinoids were stored in N2(l) as 10−2 M stock solutions in dimethylsulfoxide (DMSO), and diluted into acetone in subdued yellow fluorescent lights immediately before application to the shaved backs of mice. The test retinoids were applied 30 minutes prior to TPA.

2) Retinoid-mediated suppression of tumors in mouse skin initiation promotion of tumorigenesis: the procedures employed in this assay are those previously described [23] . Briefly, the shaved backs of CD-1 mice were painted with a single application of 51.2 µg of 7, 12-dimethylbenzanthracene (DMBA) in 0.2 mL of acetone. Two weeks later, a group of 10 shaved mice which received either only acetone or which received only DMBA, were further treated biweekly correspondingly with either TPA only, or acetone only, while the test retinoid was applied 30 minutes before TPA. The mice were examined weekly thereafter and visually scored the production of papillomas. At the 15 week termination of the trial, all TPA-treated mice were necrotized by carbon dioxide, and an exact number of tumors per animal and the area size of each tumor recorded.

3) Vitamin A-deficient bioassay: the procedures for standard hamster tracheal organ culture (HTOC) have been previously described [16] . The procedure measures the ability of a given retinoid to reverse keratinization of tracheal explants derived from hamster in early stage of vitamin A deficiency. Briefly, tracheas are stripped of adherent fat and extraneous tissue, placed in 60 mm petri dish and cultured in 2 mL of serum-free medium, placed in humidified culture boxes and cultured for 3 days without retinoids, after which they are refed fresh medium containing retinoids dissolved in DMSO or DMSO alone. Tracheas are harvested, fixed, embedded in paraffin, sectioned, stained and scored for the presence of keratin, and keratohyaline granules. As a control, we employed RA at 1 × 10−9 M which suppressed keratinization by approximately 90%.

4) Benzo(α)pyrene (BP) bioassay: the BP-HTOC bioassay is similar to that described above, except that keratinization is induced by 5.0 µg/ml of benzo(α)pyrene (BP) in the explants of normal hamster tracheas as previously described [16] .

5) Retinoid inhibition of normal and malignant keratinocyte clonal growth: the procedures employed in this bioassay are similar to those previously described [24] . Briefly, standard clonal growth assay were initiated with 500 cells per 60 mm Petri dish cultured in MCDB 153 serum-free medium supplemented with 5 ng/ml of epidermal growth factor and 5 mg/ml of porcine insulin. The dishes were gassed with 95% air and 5% carbon dioxide in a humidified incubator at 37˚C for 24 hours at which time serial dilutions of each retinoid were added to duplicate dishes and the dishes incubated for an additional 10 days, fixed, stained and the number of colonies per dish counted. The final concentrations of each retinoid were made by 10-fold serial dilutions from retinoid stock solutions (10−2 M) and ranged in concentration from 10−5 M to 10−11 M. Growth inhibition was calculated as an IC50 determined by plotting the log percent reduction of colonies per dish against concentration (M) of retinoid, and analyzed by performing a linear regression analysis to determine the significance of the result.

Statistical correlations: statistical correlations were performed by computer programs designed to test the significance of positive correlations sought between for data obtained between the different bioassays. A corresponding straight line formula was obtained for each type of correlation tested.

3. Results

Table 1 provides lists the retinoids and corresponding Southern Research Institute (SoRI) numbers. Figure 1 gives their corresponding chemical structural formulas. Additional chemical strictures are given for particular oxoretinoids and bifunctional retinoid analogs in the Results section.

3.1. Evaluation of Retinoid Suppression in Mouse Skin ODC Assay

Figure 2 presents the results obtained for the time course of ODC enzyme activity induced by a single application of TPA to the shaved backs of CD-1 mice. The peak activity routinely occurs between 4 - 5 hours post-treatment. Table 2 presents a summary of our data showing the comparative efficacy of 45 different retinoids to inhibit TPA-in- duced ODC enzyme activity. In this bioassay, each retinoid was tested by applying 17 nm of retinoid dissolved in acetone 30 minutes prior to applying 17 nm of TPA to the

Table 1. List of retinoids and their SoRI numbers.

same skin area, and the ODC enzyme activity determined. With only acetone applied post-TPA treatment applied an IC50 of 10 ODC units is consistently found, where 1 ODC value is defined as 1 nm CO 2 released/per 30 min/mg protein. This represents an 80-fold increase in stimulated activity above negligible background level in mice treatment only with acetone. As expected all-trans-retinoic acid (t-RA) was the most active (0.1 ± 0.1 SE) units; it suppressed TPA-stimulated ODC by >90%. The 13-cis-retinoid stereoisomer of t-RA was then next most active (2.2 ± 0.8 SE). Both t-RA and 13-cisRA inhibited ODC activity is a dose-dependent fashion and IC50 values of 2 × 10−11 M and 1.7 × 10−9 M, respectively. Other well-studied synthetic retinoids such as 13-cis-N-

Table 2. ODC activity of select retinoids in mouse skin.

ethylretinamide13-cis-NER) and 4-hydroxyphenylretinamide (4-HPR) had ODC units of 4.5 and 6.8, respectively and IC50 values of 1 × 10−8 M and 2 × 10−7 M, respectively. A number of novel alkyl ethers of this series were synthesized in the ODC bioassay. Trans-retinylmethyl ester (t-RME) and the TMMP analogue of t-RME had about equal activity with an IC50 value of 17nm. None of the other retinyl esters showed significant activity. Both etretinate and the TMMP analogue of t-retinol were as active in inhibiting ODC as the TMMP analogues of t-RME. Four compounds of the arotinoid series were tested. Two displayed good activity comparable to t-retinol, i.e., (E)-4-[2-5,6,7,8- tetrahydro-8,8-dimethyl-2-napthyl propenyl[phenylmethanol] and (6E,8E)-3,7-dime- thyl-9-(2,6,6-trimethylcyclohexanol 0-3,4,6,8-nonatetraen-1-01. and two others displayed good activity that was equal in efficacy to RA, i.e., (E)-4-[2-(5,6,7,8-tetrahydro- 8,8-dimethyl-2-propenyl)benzoic acid and (2E, 4E, 6E)-3-methyl-7-(5,6,7,8-tetrahy- dro-6-dimethyl-2-napthyl)-2,4,6-octarienoic acid. Figure 3 presents structural formulas for several different retinoyl amino acids. Including the trans and cis isomers of glycine and leucine and the L stereoisomers of the all trans isomers of alanine, phenylalanine, tyrosine and glutamic acid. Only the L-stereoisomers of glycine and leucine had significant activity. The addition of a second carbonyl group at the C12-C14 terminus of the retinoid skeleton was examined for possible bioactive retinoid. The dicarboxylic acid derivatives, 13 cis, 14-trans RA had sharply reduced activity relative to t-RA in the ODC bioassay. The mono-substituted trans ethyl ester of RA had moderate activity, but the diethyl ester of RA was without significant activity. Two other bifunctional derivatives were synthesized one with an ethyl ester at either the 13-cis or 14 trans positions and an N-ethyl amide at the corresponding C13-C14 position. The 13-cis ethyl ester of N-ethyl retinamide was inactive whereas the 13-cis-N-ethylretinamide of the ethyl ester of RA had moderate activity. Likewise, the 14[(ethylamino)-carbonyl]retinoic acid was

Figure 1. Chemical structural formulas and SoRI numbers of select retinoids.

Figure 2. Kinetics of TPA-induced ornithine decarboxylase activity in CD-1 mouse epidermis.

Figure 3. Time course of papilloma promotion in the MPA bioassay for: t-retinoic acid, t-RA (◊), 4-oxoretinoic acid (□), 3-methyl-4-oxoretinoic acid (∆), and DMBA/TPA control (●).

inactive, whereas the 14[(ethylamino)-13] cis-retinoic acid had good activity. Earlier, it was reported [25] that 4-oxoretinoic acid, a natural metabolite of RA, is a biological active retinoid. We examined both 4-oxoretinoic acid and more than a dozen different 3-substitute 4-oxoretinoic acids and their corresponding methyl ester (see Table 1, #s:6, 23 - 26). The majority of the all-trans-4-oxoretinoic acids derivatives had good bioactivity in the ODC bioassay equal to RA or retinol. The 3-ethyl-, 3-(2-propenyl) and 3-(2-propenyl) derivatives of 4-oxoretinoic acid were less active.

3.2. Evaluation of 4-Oxoretinoids in the Mouse Skin Papilloma Bioassay

As expected from previous HTOC results 4-oxoretinoic acid (see Table 1, SoRI 6621) was one of the best natural retinoids in suppressing tumors in the MPA bioassay. In several independent studies, there were an average of 2.0 ± 3 S.E. tumors per animal compared with RA (1.0 tumors per animal) at 15 weeks. Figure 3 presents a plot comparing the average number of tumors per animal (ordinate) against weeks of TPA promotion (abscissa) comparing the results of 4-oxoretinoic acid, and a oxoretinoic derivative, t-methyl-4-oxoretinoic acid, compared with the positive control (t-RA) and DMBA/TPA. Clearly, 4-oxoretinoic acid is nearly as effective over the time course TPA promotion as was the 3-methyl derivative relative to t-RA even as early as 12 weeks relative to DMBA/TPA. For comparison, Figure 4 presents a composite plot comparing the average number of tumors per animal (ordinate) against weeks of TPA promotion

Figure 4. Comparison of time course of papilloma promotion (weeks) in the MPA bioassay for 5 different retinoids: t-RA (○), 13-cis-retinoic acid, cis-RA (□), t-reti- noyl-glycine (▲), 4-hydroxyphenylretinamide, 4-HPR (x), t-retinyl methyl ether, t-RME (∆), and DMBA/TPA control (●).

(abscissa) for several well-studied retinoids: t-RA, 13-cis-RA, t-RME, t-RPE. 4HPR and DMBA/TPA. Interestingly, both t-RME and 4HPR actually produced more tumors over the time course of TPA-promotion than DMBA/TPA suggesting that they are themselves tumor promoters relative to the classic chemopreventive retinoids t-RA and 13- cis-RA. Both of the 3-substituted ethyl derivatives of 4-oxoretinoic acid were only marginally active. The N-17-oxoestra-1,3,5[10]-trien-2-yl retinamide had some marginal activity, while no activity was detected for the 13-cis-N-ethylretinamide indicating that retinamides are not equally active is suppressing mouse skin tumors. The TMMP analogues of retinol had no anti-tumor activity nor did any of the compounds tested in the retinyl ether and dicarboxyl retinoic acid series (Table 3).

3.3. Evaluation of Some Retinoyl-Amino Acid in the Mouse Skin Papilloma Bioassay

Figure 5 shows the general structural formula of retinoyl amino acid compounds [26] ,

Table 3. Effect of many different 4-oxoretinoic acid derivatives and some bifunctional compounds on the suppression of tumorigeneis nesis in the mouse skin papilloma bioassay.

and a list of those synthesized and tested in the MPA assay. Figure 6 presents a plot of TPA-promotion of retninoyl-glycine in comparison to t-RA, cis-RA and DMBA/TPA. Among the retinoyl-L-amino acid tested only retinoyl-L-glycine and t-retinoyl-l-leu- cine (see Figure 4) displayed marginal antitumor activity.

3.4. Evaluation of Retinoids in the HTOC Bioassay

The HTOC bioassay is widely used one of the standard procedures to assay new retinoids. Retinoids are evaluated by their ability to reverse squamous metaplasia and keratinization of the tracheal epithelium in organ explants from vitamin A-deficient hamsters.

Figure 5. Chemical structural formula for general retinoyl-amino acids and a list of 5 different retinoyl-amino acids and their abbreviations.

Figure 6. Comparison of the time-course of papilloma formation (weeks) in the MPA bioassay for: t-RA (x), 13-cis-RA (○), t-RA-gly-cine (∆), and DMBA/TPA control (●).

Recently, we developed a second HTOC assay which is rapid, reliable and more relevant to antitumor activity of retinoids. In this BP-HTOC bioassay, the carcinogen, benzo(α)pyrene is used to induce keratinizing lesions of the tracheal epithelium of normal tracheas organs cultured in Vitro. Normal tracheas cultured in control medium do not develop lesions. Table 4 presents a comparison of ED50 (M) values for 12 natural and synthetic retinoids. As previously reported [16] all of the natural retinoids t-RA, 13-cis-RA, t-retinol, 13-cis-retinol and 4-oxoretinoic acid are more effective than any of the synthetic retinoids tested. The 3-methyl -4-oxoretinoic acid had ED50 values of 4 × 10−10 M and 2 × 10−9 M, respectively in the BP-HTOC and vitamin-A deficient HTOC bioassays. The dicarboxy t-RA, 13-cis-RA had ED50 values of 3.3 × 10−9 M and 1.0 × 10−8 M, respectively in the BP-HTOC, and vitamin-A-deficient HTOC bioassays, respectively. The retinoyl-amino acids in these assay displayed only marginal effective activity as did the bifunctional methylamino carbonyl derivatives of retinoic acid. Note that the relative rank order of efficacy is the same in both assays. For other synthetic retinoids, among the retinyl esters tested in the vitamin-A-deficient HTOC bioassay, t-retinyl methyl ether (t-RME), t-retinyl propyl ether (t-RPE), t-retinyl carbonylmethyl ether (t-RCME), and 13-cis-rethyl methyl ether (cis-RME) had a ED50 value of 2.9 × 10−9 M, 5 × 10−7 M, 2.8 × 10−8 M and 1.5 × 10−8 M, respectively.

Table 4. Comparison of the BP-HTOC and the standard HTOC bioassay.

¹ED-50 values were estimated graphically from best-fitting straight lines obtained by standard methods of linear regression analysis using data derived from typical experiments.

3.5. Evaluation of Retinoids by Determining the Dose-Dependent in Vitro Inhibition of Clonal Growth of NHK and Squamous Carcinoma Cells (SCC) Bioassay

A model system has been developed to screen retinoids for antitumor potential. It involves a quantitative assay of the dose-dependent inhibition of the proliferative potential of normal human keratinocytes (NHK) cultured in a serum-free medium in the presence of increasing concentrations of the test retinoids. The rationale for this bioassay is the need for a rapid and reliable assay that correlates with antineoplastic activity in other bioassays (ODC, MPA and HTOC), and is relevant to chemoprevention in human cells. Previous studies [27] reported that all-trans-RA inhibited batch culture growth of HeLa cells and arrested their growth in the G1 phase of the cell cycle. Figure 7 shows that RA treatment of NHK cultures with 0.1 µm, 0.5 µM, 1 µM and 2 µM for 2 days inhibited growth by 20%, 23%, 33% and 40%, respectively. Flow microfluorimetry analysis showed that RA arrests NHK cells in the G1 phase of the cell cycle (41% in G1 for untreated NHK compared to 58% for RA-treated). By contrast, Figure 8 shows that 0.1 µM RA treatment of SCC-25, a squamous carcinoma cell line, led to 60% inhibition of culture growth. Flow microfluorimetry analysis of cell cycle distributions of SCC-25 treated for 2 days of culture with 2 µM RA showed a G1 arrest at 57%. This compares with 41% of cell in G1 in untreated SACC-25 cells. Figure 9 presents the results of a concentration-dependent inhibition of NHK clonal growth by t-RA. The calculated IC50 value for RA was 2 × 10−9 M. IC50 ,defined as the molar (M) concentration that inhibits 50% of the total number of colonies per dish relative to untreated control (no retinoid). Figure 10 presents the results of a concentration-dependent inhibition of SCC-25 clonal growth by t-RA. The calculated IC50 value for RA was 1 × 10−6 M. This represents an almost 3 log fold reduction in sensitivity of clonal growth inhibition by SCC-25 tumor cell line relative to normal keratinocytes. Four select retinoids, t-RA, 13-cis-RME 4- HPR and N-ER, were compared for their relative inhibitory effect on clonal growth of

Figure 7. Effect of 2 days treatment with all-trans-RA on NHK cell growth. Control untreated (black bar); Abscissa: 1 µM and 0.5 µM RA-treated cultures (grey bar). Ordinate (cell/cm2 × 10−4).

Figure 8. Effect of 2 days treatment with 1 × 10−5 M all-trans-RA on NHK cell growth. Control (left bars black-day 0; grey bar-day 2); Retinoic acid, RA (right bars (black bar-day 0, grey bard-day 2).

Figure 9. Photograph of a panel of culture dishes showing the effect of varying concentration of all-trans-RA on the inhibition of NHK clonal growth. Top row left to right: (A) 1 × 10−5 M, (B) 1 × 10−6 M, (C) 1 × 10−7 M, (D)1 × 10−8 M; bottom row left to right: (E) 1 × 10−9 M, (F) 1 × 10−10 M, and (G) 1 × 10−11 M. Total magnification: 3/4×.

NHK (Figure 11) and SCC-25 (Figure 12). The rank order of NHK sensitivity to clonal growth inhibition for these select retinoids was RA > 13-cis-RA > 4HPR > N-ER. Correspondingly, the rank order of sensitivity to inhibition of SCC-25 clonal growth for these select retinoids was identical with 2 - 3 log10 less sensitivity for SCC-25 cell line. The effect of five other retinoids (trans-retinol, cis-retinol, trans-RME, trans-retinoyl- glycine and trans-TPE) gave similar results with a rank order of sensitivity to inhibition of clonal growth identical in both NHK and SCC-25, again, with a 1 - 2 log less sensitivity for SCC-25 relative to NHK (see Table 5).

Figure 10. Photograph of a panel of culture dishes showing the effect of varying concentrations of all-trans-RA on the inhibition of SCC-25 clonal growth. Top row from left to right: (A) control RA-untreated, (B) 1 × 10−5 M, (C) 1 × 10−6 M; bottom row from left to right: (D) 1 × 10−7 M, and (E) 1 × 10−8 M. Total magnification, 1×.

Figure 11. Effect of varying concentrations of 4 select retinoids on NHK clonal growth. Ordinate: relative colony counts; abscissa: log10 M retinoid concentration; c, control untreated. t-RA (solid ◊), 13-cis-RA (?), 4-HPR (▲), and NER (X).

Figure 12. Effect of varying concentrations of 4 select retinoids on clonal growth of SCC-25 cells Ordinate: colony count per dish; abscissa: log10M retinoid concentration: c, control untreated. t-RA (solid ◊), 13-cis-RA (?), 4-HPR (▲), and NER (X).

Table 5. Effect of select retinoids on the clonal growth of NHK and SCC-25 cells.

3.6. Statistical Analysis of Retinoid Bioassays

We have examined whether there are strong positive correlations between the several different in vivo bioassay and between the different in vivo and in vitro clonal growth bioassays. Figure 13 documents a positive linear correlation for 13 different retinoids (#s:1-13) between the log ED50 (M) of the HTOC bioassay over a 5-log range and for the log reduction in TPA-induced ODC enzyme bioassay over a 95% range in suppression of ODC activity. Linear regression analysis confirms a significant positive correlation (r = 0.81. Figure 14 plots retinoid data showing a positive linear correlation exists

Figure 13. Linear correlation between vitamin A-deficient HTOC ED50, M values (abscissa) and log reduction in ODC activity for select retinoids (ordinate):1) t-RA, 2) 13-cis-RA), 3) 13-cis-NER, 4) t-RME, 5) 4-HPR, 6) t-RPE, 7) dicarboxy, t-RA/cis RA, 8) t-RA-glycine, 9) t-REE, 10) t-RA-leucine, 11) t-RA-alanine, 12) t-RA-phenylalanine, 13 13-cisRA-leucine, and 14) t-NER/cis-NER,. Best-fitting line determined by linear regression analysis.

between log reduction in papillomas per mouse over an approximately 6 log10 range and log reduction in ODC activity over a range of 95% suppression of IDCA activity. Linear regression analysis confirmed a significant positive correlation (r = 0.85). Figure 15 plots retinoid data showing a positive linear correlation exists between log reduction in papillomas per mouse and HTOC ED50 (M) values. Linear regression analysis confirmed a significant positive correlation (r = 0.88). Lastly, Figure 16 displays a linear correlation exists between log reduction in ODC activity and log IC50 (M) values for 7 different retinoids (#s:1, trans-RA; 2, 13-cis-RA; 3, 4-HPR; 4, trans-retinoyl-glycine; 5, 13-cis-NER; 6, trans-RME; 7, trans-RPE) in the inhibition of clonal growth 6 presents of both NHK and SCC-25 cells. Linear regression analysis confirms a significant positive correlation NHK (r = 0.86). Table 6 presents data for 7 retinoids (t-Ra, cis-RA, t-RME, 4-HPR, 13-cis-NER *(excluded as an outlier), t-retinoyl-glycine, and t-RPE) showing that there is a positive correlation in the rank order of retinoid sensitivity

Figure 14. Linear correlation between log reduction of papillomas per animal (abscissa) and log reduction in ODC activity for select retinoids (ordinate): 1) t-RA, 2) 13-cis-RA), 3) 13-cis-NER, 4) t- RME, 5) 4-HPR, 6) t-RPE, 7) dicarboxy, t-RA/cis RA,, 8) t-RA- glycine, 9) t-REE, 10) t-RA-leucine, 11) t-RA-alanine, 12) t-RA-phe- nylalanine, 13 13-cisRA-leucine, and 14) t-NER/cis-NER. Best-fit- ting line determined by linear regression analysis.

between log reduction in papillomas per mouse in the MPA bioassay and the log IC50 inhibition of NHK clonal growth. Linear regression analysis of the above data had a significance (r = 0.9) and p = 0.001). Remarkably, this correlation yields the same rank order of retinoid sensitivity as shown above for the correlation between log reduction in ODC activity and log IC50 inhibition of NHK clonal growth, suggesting that the NHK bioassay is by far the best method to assess new chemopreventive retinoids.

3.7. Statistical Model

The statistical analyses performed for the above bioassay data preceeded in two general directions: 1) search for statistical correlations among the assays, and 2) development of a statistical screening model. For this purpose, we examined a sample of 37 retinoids in the mouse papilloma assay and the mouse ODC enzyme induction assay for significant correlations, Using the Pearson correlation coefficient, r, we found a significant correlation r = 0.72, p = 0.0001; and using the Spearman rank correlation coefficient, R, we

Figure 15. Linear correlation between log reduction in papillomas per mouse (abscissa) and log ED50, M of the vitamin A-deficient HTOC bioassay for select retinoids (ordinate). 1) t-RA, 2) 13-cis-RA), 3) 13-cis- NER, 4) t-RME, 5) 4-HPR, 6) t-RPE, 7) dicarboxy-t-RA/cis RA, 8) t-RA-glycine, 9) t-REE, 10) t-RA-leucine, 11) t-RA-alanine, 12) t-RA- phenylalanine, 13 13-cisRA-leucine, and 14) t-NER/cis-NER. Best-fitting line (-) and second best fit line (--) excluding 13-NER as determined by linear regression analysis.

observed a correlation of R = 71, p = 0.0001. Further we developed a linear regression model to predict percentage suppression in the mouse papilloma assay using percent suppression in the ODC assay (y = −0.39 + 1.14x). To assess the predictive ability of the model, the split-half method of cross validation was used. This analysis gives a predictive root mean square error (RMSE) if 0.31 and a predictive mean bias of 0.10 for the above model. In addition, the PRESS statistic for the model was 4.8455. Correlations were also obtained for 24 retinoids on which ED50 values were available from published [16] and unpublished HTOC experiments. The correlations between suppression of ODC and log ED50 were r = −0.65, and R = −0.69, p = 0.0002 and the correlations between percentage suppression in the mouse papilloma assay and log ED50 were r = 0.59, p = 0.0024 and R = −0.65 and p = 0.0006.

Figure 16. Linear correlation beteen log reduction in ODC activity (ordinate) and -log IC50, M of NHK(●) and SCC-25(X) clonal growth bioassay (abscissa). 1) t-RA, 2) 13-cis-RA, 3) 4-HPR, 4) t-retinoyl-glycine, 5) 13-cis-NER, 6) t-RME, and 7) t-RPE.

3.8. Antineoplastic Retinoids

Retinoic acid, the most potent natural retinoid, is essential for normal cell growth and differentiation [28] . Aberrations in retinoid signaling cascade is often associated with abnormal cell growth and tumorigenesis. Currently, there are several retinoids and one rexinoid approved for treatment of specific cancers [29] . The rexinoid, 9-cis-retinoic acid is approved for the treatment of acute promyeolcytic leukemia (APL). 9-cis-reti- noid (Alitretinoin) is a form of vitamin A (Figure 17 for structural formula). It was first developed by Ligand Pharmaceutical as an antineoplastic agent. Ligand Pharmaceutical gained Food and Drug Administration approval for alitretinoin in February 1999. In gel form, Pancretin (alitretinoin) is indicated for treatment skin lesion in AIDS-related Kaposi sarcoma and to treat cutaneous T-cell lymphoma. The drug also has immune- modulating and anti-inflammatory properties. Another retinoid, bexarotene (4-[1- (5,6,7,8-tetrahydro-3,5,5,8,8-pentamethyl-2-npthalenyl)ethyenyl]benzoic acid, licensed under the trade name Targretin, is indicated for the treatment of cutaneous T-cell lymphoma (CTCL) in patient refractory to at least one prior systemic oral therapy and for topical treatment of cutaneous lesions with CTCL. Bexarotene selectively activates retinoid X receptors (RXRs) [30] [31] [32] . It induces cell differentiation and apoptosis.

Table 6. Relative effectiveness of select retinoids in suppression of TPA-induced tumors on mouse skin tumorigenesis correlated with IC-50 values in the NHK clonal growth bioassay.

Significant straight-line correlation (r = 0.9) found graphically by linear regression analysis. N.B. 13-cis-N-Ethylre- tinamide was excluded from analysis as an outlier.

As with most other vitamin-A related products Alitretinoin and Bexarotene are contraindicated for pregnant women. Alitretinoin is a substrate for cytochrome CYP3A4) detoxification enzyme system. Biochemically, 9-cis-retinoic acid is the ligand for the nuclear RXR retinoid receptor, and it also activates the retinoic acid receptor. The natural vitamin A metabolite, t-RA, also known as tretinoin has been commercialized for the topical treatment of neoplastic skin lesions, and for treatment of APL. Under the trade name Vesnoid®. The natural retinoid, 13-cis-retinoic acid has been commercialized under the trade name Isotretinoin for treatment for abnormal hyperproliferative epidermal keratinocytes and to reduce the potential for malignant degeneration. It is given as a treatment for arsenical keratosis and as an effective treatment of keratocanthomas a disease related to squamous carcinomas.

4. Discussion

Our search for bioactive retinoids as effective cancer chemopreventive agents was focused on developing and validating several different reliable bioassays. Historically, this search led to the vitamin-A deficient hamster tracheal organ culture (HTOC) method [14] [33] and was later supplemented by a more rapid, less time-consuming and yet just as reliable BP-HTOC bioassay [16] . With the development of the ornithine decarboxylase (ODC) enzyme bioassay method, an entirely independent bioassay method became available. Each of these bioassay methods has been employed to assess new classes of retinoids for their potential anti-cancer activity. An important limitation of these bioassay methods has been their failure to predict their clinical outcome in human cancer clinical trials. In particular, the therapeutic index, a measure of the ratio of beneficial dose of retinoid to risks such as toxicity, has excluded all-trans retinoic acid (t-RA) and other promising retinoids. Nevertheless, several anti-neoplastic retinoids are in use today (reviewed here). In order to continue the effort to discover new potent and safe anticancer retinoid drugs, we have developed a rapid, reliable, and more relevant bioassay method based on the ability of select retinoids to inhibit the clonal growth of normal human keratinocytes. This bioassay method was validated here by demonstrating its ability to rank order a retinoid’s sensitivity to inhibit clonal growth that correlated with that same test retinoids ability to suppress ODC activity. In this regard, we showed that the rank order of sensitivity of a given retinoid to inhibit clonal growth extends to SCC-25, a human epidermoid carcinoma cell line. Of interest was the finding that for each retinoid tested the tumor cells were less sensitive to retinoid inhibition of clonal growth. A note of caution is the possibility of toxicity and cell death at retinoid concentrations above 1 × 10−6 M, which could limit the detection of retinoid bioactivity. Earlier, we reported [34] that all-trans-RA prevents super-induction of benzo(α)pyrene-induced aryl hydrocarbon hydroxylase enzyme in serum-free NHK cultures, indicating that RA suppresses metabolic activation of arylhydrocarbon carcinogenesis. Further, we reported that RA effectively inhibits phosphoprotein kinase activity regulating the proliferation of both NHK and SV-40 transformed keratinocytes [35] . These latter findings could lead in the future to more specific biochemical retinoid bioassay methods.

Acknowledgements

We acknowledge the previous support of USPHS grant PO1 CA 34968 and NCI Contract NO1-CP-26009 to Southern Research Institute, Birmingham, AL. We wish thank Michael Hardin of Southern Research Institute for his assistance with the statistical analysis and statistical model development and Gloria Triggs for her excellent animal technical bioassay work.

Conflicts of Interest

The authors declare no conflicts of interest.

References

[1] Weinberg, R.A. (2007) The Biology of Cancer. Garland Sciences, Taylor and Francis Group, Milton Park.
[2] De Luca, L.M. and Shapiro, S.S. (1981) Modulation of Cellular Interactions by Vitamin A and Derivatives (Retinoids). Annals of the New York Academy of Sciences, Vol. 359.
[3] Bollag, W. (1972) Prophylaxis of Chemically Induced Benign and Malignant Epithelial Tumors by Vitamin A Acid (Retinoic Acid). European Journal of Cancer, 8, 689-693.
https://doi.org/10.1016/0014-2964(72)90153-3
[4] Sporn, M.B., Dunlop, N.M., Newton, D.L. and Smith, J.M. (1976) Prevention of Chemical Carcinogenesis by Vitamin A and Its Synthetic Analogs (Retinoids). Federation Proceedings, 35, 1332-1338.
[5] Comic, M., Guidez, F., Delva, L., Agadir, A., Degos, L. and Chomienne, C. (1992) Mechanism of Action of Retinoids in a New Therapeutic Approach to Acute Promyelocytic Leukemia. Bulletin du Cancer, 79, 697-704.
[6] Freemantle, S.J., Spinella, M.J. and Dmitrovsky, E. (2003) Retinoids in Cancer Therapy and Chemoprevention: Promise Meets Resistance. Oncogene, 22, 7305-7315.
https://doi.org/10.1038/sj.onc.1206936
[7] Freemantle, S.J., Dragneva, K.H. and Dmitrovsky, E (2006) The Retinoic Acid Paradox in Cancer Chemoprevention. Journal of the National Cancer Institute, 98, 426-427.
https://doi.org/10.1093/jnci/djj116
[8] Dragneva, K.H., Rigasa, J.R. and Dmitrovsky, E. (2000) The Retinoids and Cancer Prevention Mechanisms. The Oncologist, 5, 361-368.
https://doi.org/10.1634/theoncologist.5-5-361
[9] Nagpal, S. (2004) Retinoids: Inducers of Tumor/Growth Suppressors. Journal of Investigative Dermatology, 123, 20-21.
https://doi.org/10.1111/j.0022-202x.2004.23533.x
[10] Tang, X.H. and Gudas, L.J. (2011) Retinoids, Retinoic Acid Receptors and Cancer. Annual Review of Pathology, 6, 345-364.
https://doi.org/10.1146/annurev-pathol-011110-130303
[11] Uray, I.P., Dmitrovsky, E. and Brown, P.H. (2016) Retinoids and Rexinoids in Cancer Preventionz: From Laboratory to Clinic. Seminars in Oncology, 43, 49-64.
https://doi.org/10.1053/j.seminoncol.2015.09.002
[12] Bushue, N. and Wan, Y.-J. (2010) Retinoid Pathway and Cancer Therapeutics. Advanced Drug Delivery Reviews, 62, 1285-1298.
https://doi.org/10.1016/j.addr.2010.07.003
[13] Shealy, Y.F., Frye, J.L., O’Dell, A., Thorpe, M.C., Kirk, M.C., Coburn Jr., W.C. and Sporn, M.C. (1984) Synthesis and Properties of Some 13-Cis-and All-Trans-Retinamides. Journal of Pharmaceutical Sciences, 73, 745-751.
https://doi.org/10.1002/jps.2600730610
[14] Newton, D., Henderson, W.R. and Sporn, M.B. (1980) Structure-Activity Relationship of Retinoids in Hamster Tracheal Organ Culture. Cancer Research, 40, 3413-3425.
[15] Sporn, M.B. and Roberts, A.B. (1984) Biological Methods of Analysis and Assay of Retinoids. In: Sporn, M.B., et al., Eds., Retinoids, Acdemic Press, Orlando, Vol. 1.
https://doi.org/10.1016/B978-0-12-658101-0.50011-1
[16] Wille, J.J. and Chopra, D.P. (1988) Reversal by Retinoids of Keratinization Induced by Benzo(α)Pyrene in Normal Hamster Tracheal Explants: Comparison with the Assay Involving Organ Culture of Tracheas from Vitamin A-Deficient Hamsters. Cancer Letters, 40, 235-246.
https://doi.org/10.1016/0304-3835(88)90082-1
[17] Sani, B.P., Dawson, M.I., Hobbs, P.D., Chan, R.L.C. and Schiff, L.J. (1984) Relationship between Binding Affinities to Cellular Retinoic Acid-Binding Proteins and Biological Potency of a New Series of Retinoids. Cancer Research, 44, 190-195.
[18] Dawson, M.L., Hobbs, P.D., Derdzinski, K.A., Chao, W.-R., Frenking, G., Loew, G.H., Jetten, A.M., Napoli, J.L., Williams, J.B., Sani, B.P. and Wille Jr., J.J. (1989) Effect of Structural Modifications in the C7-C11 Region of the Retinoid Skeleton on Biological Activity in a Series of Aromatic Retinoids. Journal of Medicinal Chemistry, 32, 1504-1517.
https://doi.org/10.1021/jm00127a018
[19] Sani, B.P., Wille Jr., J.J., Dawson, M.I., Hobbs, P.D., Bupp, J., Rhee, S., Chao, W.-R., Dorsky, A. and Morimoto, H. (1989) Biologically Active Aromatic Retinoids Bearing Azido Photoaffinity Labeling Groups and Their Binding to Cellular Retinoic Acid-Binding Protein. Chemico-Biological Interactions, 75, 293-304.
https://doi.org/10.1016/0009-2797(90)90072-U
[20] Dawson, M.I. and Chao, W.-R. (1988) Comparison of the Inhibitory Effects of Retinoids on 12-0-Tetradecanoylphorbol-13-Acetate-Promoted Tumor Formation in CD-1 and Sencar Mice. Cancer Letters, 40, 7-12.
https://doi.org/10.1016/0304-3835(88)90256-X
[21] Verma, A.K., Rice, H.M., Shapas, B.G. and Boutwell, R.K. (1978) Inhibition of 12-O-Tetra-decanoylphorbol-13-Acetate-Induced Ornithine Decarboxylase Activity in Mouse Epidemis by Vitamin A Analogues (Retinoids). Cancer Research, 38, 793-801.
[22] Verma, A.K., Shapas, B.G., Rice, H.M. and Boutwell, R. (1979) Correlation of the Inhibition by Retinoids of Tumor Promoter-Induced Mouse Epidermal Ornithine Decarboxylase Activity and Skin Tumor Promotion. Cancer Research, 39, 419-425.
[23] Verma, A.K. and Boutwell, R.K. (1977) Vitamin A Acid (Retinoic Acid), a Potent Inhibitor of 12-O-Tetradecanoyl-Phorbol-13-Acetate-Induced Ornithine Decarboxylase Activity in Mouse Epidermis. Cancer Research, 37, 2196-2201.
[24] Wille Jr., J.J., Pittelkow, M., Shipley, G. and Scott, R.E. (1984) Integrated Control of Growth and Differentiation of Normal Human Prokeratinocytes Cultured in Serum-Free Medium: Clonal Analyses, Growth Kinetics, and Cell Cycle Studies. Journal of Cellular Physiology, 121, 31-44.
https://doi.org/10.1002/jcp.1041210106
[25] Frolik, C.A., Roberts, A.B., Tavela, T.E., Roller, P.P., Newton, D.L. and Sporn, M.B. (1979) Isolation and Identification of 4-Hydroxy- and 4-Oxoretinoic Acid, in Vitro Metabolites of All-Trans-Retinoic Acid in Hamster Trachea and Liver. Biochemistry, 18, 2092-2097.
https://doi.org/10.1021/bi00577a039
[26] Shealy, Y.F., Frye, J.L. and Schiff, L.J. (1988) N-(Retinoyl)Amino Acids. Synthesis and Chemopreventive Activity in Vitro. Journal of Medicinal Chemistry, 31, 190-196.
https://doi.org/10.1021/jm00396a031
[27] Dion, L.D. and Gifford, G.E. (1980) Retinoic Acid Induces a G1 Cell Cycle Block in HeLa Cells. Proceedings of the Society for Experimental Biology and Medicine, 163, 510-514.
https://doi.org/10.3181/00379727-163-40806
[28] Livrea, M.A. and Packer, L. (1993) Retinoids: Progress in Research and Clinical Applications. Marcel Dekker Inc., New York.
[29] Buletic, Z., Soprano, K.J. and Soprano, D.R. (2006) Retinoid Targets for the Treatment of Cancer. Critical Reviews in Eukaryotic Gene Expression, 16, 193-210.
https://doi.org/10.1615/CritRevEukarGeneExpr.v16.i3.10
[30] Rowe, A. (1997) Retinoid X Receptors. International Journal of Biochemistry & Cell Biology, 29, 275-278.
https://doi.org/10.1016/S1357-2725(96)00101-X
[31] Dawson, M.I. and Xia, Z. (2012) The Retinoid X Receptors and Their Ligands. Biochimica et Biophsica Acta, 1821, 21-56.
https://doi.org/10.1016/j.bbalip.2011.09.014
[32] Qu, L. and Tang, X. (2010) Bexarotene: A Promising Anticancer Agent. Cancer Chemotherapy and Pharmacology, 65, 201-205.
https://doi.org/10.1007/s00280-009-1140-4
[33] Wattenberg, L.W. and Lam, L.K.T. (1981) Inhibition of Chemical Carcinogenesis by Phenol, Coumarins, Aromatic Isothiocyanites, Flavones, Indoles, and Retinoids. In: Zideck, M.S. and Lipkin, M., Eds., Inhibition of Tumor Induction and Development, Vol. 1, Plenum Press, New York, 1-19.
[34] Wille, J.J. and Park, J.Y. (2012) Retinoid and Ethanol-Sensitive Benzo(α)pyrene Induction of Cytochrome P450 in Human Keratinocytes. Journal of Cancer Therapy, 3, 1080-1085.
https://doi.org/10.4236/jct.2012.36141
[35] Wille, J.J. and Park, J.Y. (2014) Effects of Okadaic Acid, Retinoic Acid, and Phorbol Myristate Acetate Tumor Promoter on Oncogene Expression. Journal of Cancer Therapy, 5, 591-604.
https://doi.org/10.4236/jct.2014.56068

Copyright © 2024 by authors and Scientific Research Publishing Inc.

Creative Commons License

This work and the related PDF file are licensed under a Creative Commons Attribution 4.0 International License.