Effects of an aqueous extract of processed bidi tobacco on the growth of hamster tracheal epithelial cells.

Inhalation of tobacco dust is responsible for elevated genotoxicity and pulmonary ailments in workers engaged in processing tobacco for the manufacture of bidis, the Indian version of cigarettes. Tracheal tissue being the major site of interaction with tobacco dust, the effects of different concentrations of an aqueous extract of bidi tobacco (ATE) on the growth of a hamster tracheal epithelial cell line (HTE) were investigated. Colony forming efficiency assay revealed that ATE was cytotoxic only at the highest concentration of 5.0 mg/ml. In cultures treated with 1.25 mg/ml ATE, the cell doubling time and growth rate were similar to that of the controls, while a significant increase in cell doubling time (29.4+/-0.3 h vs 14.0+/-3.75 h, P<0.001) was observed at 2.5 mg/ml ATE concentration. Exposure of HTE cells to the non-toxic ATE concentration of 2.5 mg/ml was found to stimulate ornithine decarboxylase (ODC) activity, incorporation of [3H] methyl thymidine into DNA and increase in the S phase fraction was seen by flow cytometry. However, a 56% reduction in the growth rate of cultures treated with 2.5 mg/ml ATE was related to the prolongation of the traverse of cells through S phase. ATE-induced growth suppression was reversed when cultures were grown in ATE-free medium or upon repeated exposure to ATE. The findings suggest that increased tracheal cell proliferation induced by chronic inhalation of tobacco dust may contribute to the development of pulmonary disorders and possibly neoplasia in exposed individuals.

Long-term carcinogenicity of pan masala in Swiss mice.

Carcinogenicity of pan masala, a dry powdered chewing mixture of areca nut, catechu, lime, spices and flavoring agents was evaluated by means of the long-term animal bio-assay 6- to 7-week old male and female S/RVCri mice were divided randomly into intermediate and lifetime exposure groups and fed normal diet without pan masala-(zero dose) or diet containing 2.5% and 5% pan masala. Animals in the intermediate-exposure group (n = 10/gender/dose group) were killed after 6, 12 or 18 months of treatment, while those in the lifetime-exposure group (n = 54/gender/dose group) were killed when moribund or at the termination of the experiment at 24 months. Several tissues were processed for histopathological examination. The body weight and survival rate of mice fed pan masala were lower than that of the controls. Histopathological observations of tissues from control animals did not reveal any neoplastic alterations. However, lifetime feeding of pan masala induced adenoma of the liver, stomach, prostate and sebaceous glands, also forestomach papilloma, liver hamartoma, hepatoma and hemangioma, carcinoma of the forestomach, adenocarcinoma of the lung and liver, and testicular lymphoma. Neoplastic lesions appeared mainly in the liver (n = 13), stomach (n = 3) and lung (n = 8). Lung adenocarcinoma, the most frequent malignant tumor type, was observed in 2/120 mice in the intermediate-exposure group and in 8/216 animals in the lifetime-exposure group. Statistical analysis of tumor-induction data revealed a significant dose-related increase in lung adenocarcinomas but not in liver and stomach neoplasms indicating that lung is the major target tissue for the carcinogenic action of pan masala.

Evaluation of carcinogenic/co-carcinogenic activity of a common chewing product, pan masala, in mouse skin, stomach and esophagus.

Pan masala, a dry powdered mixture of areca nut, catechu, lime, unspecified spices and flavoring agents, has gained widespread popularity as a chewing substitute in India. In this study, the carcinogenic and tumor-promoting potential of an ethanolic pan masala extract (EPME) was determined using skin of S/RVCri-ba mice and forestomach and esophagus of ICRC mice as the target tissues. Carcinogenic activity of pan masala was tested by painting the mouse skin for 40 weeks with EPME or by gavage feeding for 6 months. Following initiation with 9,10-dimethylbenz(a)anthracene (DMBA), carcinogenesis of mouse skin was promoted with different doses of EPME, while gastric- and esophageal-tumor-promoting activity was determined by administering EPME by gavage to animals initiated with diethylnitrosamine (DEN). The ability of EPME to effect progression of skin papilloma to carcinoma and cutaneous alterations after a single or multiple EPME treatment were also evaluated. EPME at 25 mg per dose promoted skin-papilloma formation between 30 and 40 weeks of treatment and enhanced the rate of conversion of papilloma to carcinoma. Induction of mild epidermal hyperplasia, dermal edema, increase in epidermal mitotic activity and the rate of epidermal and dermal DNA synthesis by EPME correlated well with its skin-tumor-promoting potential. In ICRC mice, EPME was inactive as a complete carcinogen, but effectively promoted the development of forestomach and esophageal papilloma and carcinoma in a concentration-dependent manner. The tumor incidence at 25 mg EPME per dose was comparable with that obtained in the 12-O-tetradecanoylphorbol-13 acetate(TPA)-treated group. The findings indicate that habitual pan-masala use may exert carcinogenic and co-carcinogenic influence.

Skin-tumour-promoting activity of processed bidi tobacco in hairless S/RV Cri-ba mice.

Workers engaged in processing tobacco for the manufacture of bidis, the most popular smoking devices in India, are exposed to tobacco dust, volatile components and flakes via nasopharyngeal and cutaneous routes. In order to evaluate the risk of occupational tobacco exposure, the complete carcinogenic action of an aqueous extract of bidi tobacco (ATE), its ability to initiate and promote skin papillomas and to convert these to carcinomas, was tested in hairless S/RV Cri-ba mice using the skin tumorigenesis protocol. Epidermal cell kinetics and tissue alterations were recorded after a single or multiple applications of ATE to 7,12-dimethylbenz[a]-anthracene(DMBA)- initiated mouse skin. While ATE did not exhibit complete carcinogenic, initiating or progressor activity, it effectively promoted skin papilloma formation in DMBA-initiated mice. An increase in papilloma yield per mouse above the control was noted only after 30 weeks of promotion, and at week 40 of promotion with 5 mg and 50 mg ATE it was significantly higher than that in the control mice (9.69 +/- 1.30 and 11.73 +/- 1.38 compared to 4.70 +/- 1.01; P < 0.01). Mild epidermal hyperplasia, increase in mitotic activity and dermal thickness induced by a single application of ATE persisted upon multiple treatment and correlated well with its tumour-promoting activity. The findings indicate that occupational exposure to bidi tobacco may pose a cancer risk among workers in the bidi industry.

Inversion of carcinogen-promoter sequence: effects on mouse skin tumorigenesis and cellular growth kinetics.

To stimulate conditions wherein humans might be exposed to tumor promoters prior to carcinogenic stimulus, female S/RV Cri mice were treated with 12-O-tetradecanoylphorbol-13-acetate (TPA) for 10 weeks followed by a sc injection of 3-methylcholanthrene (MCA). Six weeks after MCA administration, tissue alterations in different skin layers were analysed by histology, morphometry and autoradiography. Multiple application of TPA prior to MCA injection induced moderate to marked epidermal hyperplasia with an increase in the thickness of nucleated cell layers and stratum granulosum. As compared to control, number of basal and suprabasal cells per 7.5 mm of interfollicular epidermal (IFE) length was significantly higher in the skin of animals treated with TPA + MCA. The hyperplastic response was accompanied by a significant increase in epidermal mitotic activity, number of cells in DNA-synthetic phase in epidermis, dermis and subcutis and subepidermal mast cell population. Histological observations of induced tumors revealed a significant increase in the incidence of carcinomas and mixed neoplasms of epithelial and mesenchymal histogenesis. The findings suggest that stimulated cellular proliferation in different layers of mouse skin by TPA treatment prior to MCA injection may play a major role in enhanced expression of histogenetically distinct tumors.

Correlation between tissue growth kinetics and modulation of mouse skin tumorigenesis by phorbol esters.

Previous studies on the influence of phorbol esters on mouse skin tumorigenesis have shown that 12-O-tetradecanoylphorbol-13-acetate (TPA) enhances development of malignant epithelial and mesenchymal skin tumors by a completely carcinogenic dose of 3-methylcholanthrene (MCA), while its congener phorbol-12, 13-diacetate (PDA) exerts an inhibitory effect. Differential effects of these two agents were analysed by histology, morphometry and cell kinetic techniques including autoradiography and estimation of labelled precursor incorporation into DNA by liquid scintillation counting. Epidermal hyperplasia induced on exposure of S/RV Cri mouse skin to a single or multiple TPA application after MCA injection was associated with a significant increase in the thickness of nucleated cell layers, stratum granulosum, number of suprabasal cells and dark basal cells. Enhancing effect of TPA on MCA-induced neoplastic development correlated well with an increase in mitotic activity, number of cells in S-phase and increased rate of DNA synthesis in the epidermis, dermis and subcutis as also mast cell number. In contrast, treatment of MCA-injected preneoplastic mouse skin with PDA resulted in epidermal hypoplasia and cellular damage evident as cytoplasmic vacuolation and nuclear pyknosis. Multiple PDA exposure also reduced the thickness, mitotic index and number of cells in S-phase in epidermis, dermis and subcutis. Thus, cellular toxicity and inability to recruit cells in DNA-synthetic phase may account for inhibition of progression of preneoplastic epithelial and mesenchymal cells into overt tumors by PDA.

Influence of short-term topical exposure to phorbol ester tumor promoters on subcutaneously induced skin tumorigenesis in S/RVCri mice.

The effects of short-term exposure to phorbol ester tumor promoters on epithelial and mesenchymal skin tumor induction, studied histologically in female S/RVCri mice, rendered precancerous by a subcutaneous (sc) injection of 3-methylcholanthrene (MCA). At 6 weeks after MCA injection, mice in Groups I to VI received topical twice weekly applications of 0.1 ml acetone, 1.8 nmol 12-O-tetradecanoylphorbol-13-acetate (TPA), phorbol didecanoate (PDD), phorbol dibenzoate (PDB), phorbol diacetate (PDA) or 6.1 nmol mezerein (MEZ) in 0.1 ml acetone, respectively, for four weeks. Animals were sacrificed after the development of palpable tumors. Data from various phorbol ester treatment groups were compared with the acetone control. Of the promoters tested, TPA treatment increased the percentage of tumor bearers and the number of combinations and expression of diverse neoplasms in the mixed growths. TPA-related phorbol esters such as PDD, PDB or MEZ did not alter the percentage of tumor bearers although the histological distribution into pure epithelial or mesenchymal and mixed tumor bearers differed significantly from the control treated with the solvent alone. However, PDA significantly inhibited MCA-induced skin tumorigenesis and increased the average time of tumor induction. All the promoters, except TPA, decreased the percentage of mixed tumor bearers, the development of hibernoma and fibrosarcoma, while allowing a selective expression of rhabdomyosarcoma.

Differential effects of phorbol ester tumor promoters on 3-methylcholanthrene-induced epithelial and mesenchymal skin tumorigenesis.

The effects of TPA, PDD, PDB, PDA, or MEZ on epithelial and mesenchymal skin tumors induced by a s.c. injection of MCA were studied histologically. Group-I mice received only MCA. At 6 weeks after MCA injection, mice in groups II to VII received acetone, 1.8 nmol TPA, PDD, PDB, PDA, or 6.1 nmol MEZ respectively in 0.1 ml acetone twice weekly until tumor development. Alterations in skin tumor induction patterns were also studied in animals that had been exposed to TPA or acetone for 10 weeks prior to s.c. injection of MCA. Exposure of mouse skin to TPA before or after carcinogen administration increased 2- to 3.5-fold, the incidence of carcinoma and mixed tumors of epithelial and mesenchymal histogenesis. The average time of tumor induction decreased in mice treated with MCA + TPA and 100% of the test animals in the TPA + MCA group developed tumors. In contrast, TPA-related phorbol esters inhibited skin tumor development, particularly trichoepithelioma and fibrosarcoma and increased the average time of tumor induction.

Effects of 12-O-tetradecanoylphorbol-13-acetate on the incorporation of labelled precursors into RNA, DNA and protein in epidermis, dermis and subcutis from precancerous mouse skin with reference to enhanced tumorigenesis.

The effects of a single application of 1.8 nmol 12-O-tetradecanoylphorbol-13-acetate (TPA) on precursor incorporation into RNA, DNA and protein in the epidermis, dermis and subcutis from 3-methylcholanthrene (MCA) injected precancerous mouse skin were studied at various time points between 3 and 96 h. In the precancerous tissues, the rates of incorporation of [3H]uridine into RNA did not alter appreciably from those in the control tissues; while the rates of [3H]methylthymidine incorporation into DNA were elevated with peaks appearing between 6 and 12 h, at 24 h and at 72 h in epidermis, dermis and subcutis. The rate of incorporation of [14C]leucine into protein was markedly elevated in all the three tissues which showed 3-4 sharp peaks. The maximum stimulation ranged between 14 and 20 times that of the control. A single application of TPA to the precancerous mouse skin induced early stimulation of precursor incorporation into all the three macromolecules in epidermis, dermis and subcutis. The increased stimulation was maintained for 36-72 h. The patterns of incorporation of [3H]methylthymidine into DNA gave rise to 2-3 peaks of elevated uptake in each tissue up to 36-48 h. A lowered rate of DNA synthesis between 48 and 60 h was followed by a peak at 72 h. In each group, epidermal mitotic activity correlated well with spurts of precursor incorporation into cellular DNA. The observations indicate that TPA recruits more cells into the DNA synthetic phase and accelerates selective growth of preneoplastic cells during tumor progression.

12-0-Tetradecanoylphorbol-13-acetate-induced amplification of mesenchymal tumorigenesis in the mouse skin.

Skin tumors were induced in 6-week-old female Swiss albino mice by a single subcutaneous (SC) injection of 20-methylcholanthrene (MCA) in the right scapular region and the animals were then divided into four groups. Mice in group I did not receive further treatment. Six weeks after MCA injection, those in groups II and III received twice weekly applications of 0.1 ml acetone and 1.8 nmol 12-0-tetradecanoylphorbol-13-acetate (TPA) in 0.1 ml acetone, respectively, at the site of MCA injection until tumor development. Group IV animals were divided into four subsets and administered two, four, six, or eight TPA applications commencing 6 weeks after carcinogen injection. The effect of TPA pretreatment on MCA-induced tumorigenesis was studied in animals in group V. In mice treated with MCA alone, the most predominant mesenchymal tumor type is fibrosarcoma with induction of some rhabdomyosarcomas. Mixed mesenchymal tumors consisting of fibrosarcoma, rhabdomyosarcoma, or hibernoma were observed in only 12% of the animals. The number of animals bearing mixed mesenchymal tumors such as fibrosarcoma, rhabdomyosarcoma, hibernoma, and/or liposarcoma increased to 46% in mice receiving MCA + TPA until tumor development. Interestingly, liposarcomas were not found at all in animals treated with MCA alone. The data indicates that TPA application to precancerous mouse skin enhances mesenchymal tumorigenesis.