* Covance Laboratories, Inc., 3301 Kinsman Boulevard, Madison, Wisconsin 53704;
Pfizer, Inc., Central Research, Eastern Point Road, Groton, Connecticut 06340; and
DuPont Haskell Laboratory for Toxicology and Industrial Medicine, P.O. Box 50, Newark, Delaware 19714
Received August 14, 2000; accepted October 11, 2000
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ABSTRACT |
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Key Words: peroxisome proliferators; estradiol; Leydig cell.
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INTRODUCTION |
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An initial hypothesis for the mechanism of induction of Leydig cell tumors was that there was an increase in peroxisomes, and the tumor induction occurred in a manner similar to that of the liver. However in a series of short-term studies, which used both electron microscopy and biochemical methods, it was found that C8 and WY do not induce peroxisome production in the Leydig cells (Biegel et al., 1992), although peroxisomes are present in this cell type. Additionally, C8 was found to decrease testosterone and increase estradiol concentrations in vivo and directly inhibit testosterone production when incubated with isolated Leydig cells (Biegel et al., 1995
). Several other peroxisome proliferators have also been shown to inhibit testosterone production using isolated Leydig cells (Liu et al., 1996a
). Therefore, it appears that Leydig cell tumors are not due to an increase in peroxisomes, but may be due to a disruption of the hypothalamic-pituitary-testicular (HPT) axis. To further investigate the relationship between peroxisome-proliferating compounds and hepatic and Leydig cell tumorigenesis, a 2-year feeding study was initiated using Wyeth-14,643 (WY) and ammonium perfluorooctanoate (C8) to test the hypothesis that peroxisome-proliferating compounds induce a tumor triad (liver, Leydig cell, pancreatic acinar cell) and to examine the potential mechanism for the Leydig cell tumors. The CD rat was selected because it has a low spontaneous incidence of Leydig cell tumors (
5%) (Cook et al., 1999
; Lang, 1992
). C8 was selected because it has been shown to produce Leydig cell adenomas and also induce peroxisome proliferation. WY was selected as a model for the class of compounds known to be peroxisome proliferators, and it is a potent inducer of hepatic peroxisomes and hepatocellular carcinoma (Marsman et al., 1988
). WY has not been reported to produce Leydig cell tumors; however, all the bioassay studies conducted to date have used the F344 strain of rat. Therefore, this study will determine whether exposure to WY will produce Leydig cell tumors in a CD rat at a dietary concentration that produces liver tumors. Six months into this study, hydrochlorofluorocarbon 123 (HCFC-123), a known peroxisome proliferator, was shown to produce pancreatic acinar cell tumors (Malley et al., 1995
), this finding prompted the addition of the pancreas as an endpoint in this mechanistic bioassay.
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MATERIALS AND METHODS |
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C8 and WY were added to PMI® Feeds, Inc. Certified Rodent Diet #5002 (St Louis, MO) and thoroughly mixed for approximately 6 min in a high-speed Hobart mixer to assure homogeneous distribution in the diet. Analyses of the diets determined that the test compounds were homogeneously distributed. During the test period, rats in each group were fed, ad libitum, a diet of PMI® Feeds, Inc. Certified Rodent Diet #5002, which contained 0, 300 ppm C8, or 50 ppm WY. The concentration of WY was decreased to 25 ppm on test day 301, due to increased mortality. As a result, no WY-treated rats were sacrificed for biochemical or pathological evaluation at the 15-month time point.
Test species.
Twenty-one day old male Crl:CD® BR (CD) rats were purchased from Charles River Breeding Laboratories (Raleigh, NC). Upon receipt, rats were placed in stainless steel, wire mesh cages, individually housed, and quarantined for 3 weeks. The rats were released from quarantine by the laboratory veterinarian and selected for the study on the bases of body weights and freedom from clinical signs of disease or injury during the quarantine period. Rats were then divided by computerized, stratified randomization into treatment groups so that there were no statistically significant differences among group body weight means. Rats were assigned to the ad libitum control group (control), control pair-fed rats to the C8 group (CP-C8), the 300-ppm C8 group, or the 50-ppm WY group. After assignment to treatment groups (n = 156/group), each rat was assigned a unique 6-digit number, and designated for either hormonal evaluation (10/group/time point), cell proliferation evaluation (6/group/time point), or evaluation of peroxisome proliferation (6/group/time point). Animal rooms were maintained at a temperature of 23 ± 1°C, a relative humidity of 50 ± 10%, and were artificially illuminated (fluorescent light) on a 12-h light/dark cycle (approximately 06001800 hours). In a few instances, the temperature/humidity were outside the acceptable ranges, but the magnitude/duration were minimal and judged to be of no consequence. All rats were provided tap water and PMI® Feeds, Inc. Certified Rodent Diet #5002, ad libitum. All rats were approximately 49 days of age on the day of study start.
All rats were housed individually in stainless steel, wire-mesh cages during the test period. Cage-side examinations were conducted at least once daily throughout the study. At each weighing, rats were individually handled and carefully examined for abnormal behavior and/or appearance. Rats were weighed once a week during the first 3 months and once every other week for the remainder of the study. Rats pair-fed to the C8 group had food consumption determined twice per week for the first 3 weeks. The CP-C8 group then received the same amount of food consumed by the C8-treated rats in the previous food consumption or weighing interval. Feed jars containing the mean daily food consumption were replaced daily. After the first 3 weeks, the amount of food consumed by each test group was determined weekly and, after 3 months, every 2 weeks. From these determinations and mean body weight data, mean daily food consumption, mean food efficiency, and intake of the test compounds were calculated.
Hormonal measurements.
Ten rats from each group were randomly selected at each sampling time point for hormonal analysis. Blood was collected from the tail vein approximately 1, 3, 6, 9, 12, 15, 18, and 21 months after initiation of the study. For blood collection, rats were restrained using Narco Bio-Systems (Houston, TX) heated restrainers and blood was collected without anesthesia. Serum was prepared and frozen between 65 and 85°C until analyzed for testosterone, estradiol, luteinizing hormone (LH), follicle stimulating hormone (FSH), and prolactin concentrations. At each sampling time point, all serum samples were analyzed simultaneously in duplicate, using the same lot number kit for each of the designated hormones, in order to reduce variability. Testosterone (catalog #TKTT5) and estradiol (catalog #KE2D5) concentrations were determined using radioimmunoassay kits from Diagnostic Products Corp. (Los Angeles, CA). FSH (catalog #RPA.550), LH (catalog #RPA.552), and prolactin (catalog #RPA.553) concentrations were determined using radioimmunoassay kits from Amersham Corp. (Arlington Heights, IL).
Pathological evaluation.
Rats were euthanized at interim time points 1, 3, 6, 9, 12, 15, 18, and 21 months. At each time point, 6 rats/group were selected for evaluations of cell proliferation and 6/group for peroxisome proliferation. Rats were euthanized by chloroform anesthesia and exsanguination. Testes, epididymides, accessory sex gland (ASG) unit with fluid, coagulating gland/seminal vesicle with fluid removed, prostate, and liver were weighed. Immediately after weighing, the liver and testes from animals selected for peroxisome proliferation evaluation were placed in ice-cold homogenization buffer for peroxisomal preparation. The following tissues were collected from rats selected for cell proliferation evaluation: testes, epididymides, ASG, liver, duodenum, pituitary, and all organs with gross lesions.
All rats surviving the 24-month test period were euthanized by chloroform anesthesia and exsanguination and were necropsied. Brain, heart, liver, spleen, kidneys, ASG unit, coagulating gland/seminal vesicles with fluid removed, prostate, epididymides, and testes were weighed at necropsy. The liver, testes, epididymides, pancreas, and organs with gross lesions were examined microscopically; single sections were examined on H & E stained slides. The morphologic criteria for diagnosis of proliferative pancreatic lesions were based on the recommendations of Hansen and co-workers (1995), which defines a proliferative acinar lesion as an adenoma if the diameter is greater than or equal to 5 mm. A Leydig cell adenoma was defined as a lesion with a diameter greater than 3 tubules.
Cell proliferation evaluation.
Six days prior to euthanization at each of the time points, animals designated for cell proliferation evaluation were anesthetized by an injection of ketamine and xylazine, and Alzet® osmotic pumps (Palo Alta, CA) containing 20 mg/ml 5-bromo-2'-deoxyuridine (BrdU) dissolved in 0.5 N sodium bicarbonate buffer were implanted subcutaneously. At sacrifice, tissues were collected and fixed for cell proliferation analysis. The labeling index was determined for hepatocytes and Leydig cells at each of the specified time points. Additionally, the pancreas was collected at the 9-, 12-, 15-, 18-, and 21-month time points and labeling indices for pancreatic acinar cells were determined. The duodenum was used as a positive control for staining of labeled cells. For each tissue type, one thousand cells were scored.
Peroxisomal preparation.
ß-Oxidation activity from the liver and Leydig cell peroxisomes was measured at all of the interim time points from rats designated for evaluation of peroxisome proliferation. The livers were homogenized (1 g tissue/4 ml buffer) in homogenization buffer (0.1 M potassium phosphate buffer at pH 7.4, containing 0.25 mM sucrose, 1.0 mM EDTA, 2.0 mM glutathione, 4.0 mM magnesium chloride, and 50 µM leupeptin) with a polytron. The testes were decapsulated, digested with collagenase, and Leydig cells were isolated from Percoll gradients according to the method of Biegel and co-workers (1992). The Leydig cells were resuspended in homogenization buffer and homogenized with a polytron. The liver and Leydig cell homogenates were centrifuged at 600 x g for 15 min at 2°C. The 600 x g supernatant was removed and centrifuged at 15,000 x g for 15 min at 2°C. The 15,000 x g pellet was resuspended in a final volume of 4.0 ml homogenization buffer, aliquoted, and stored between 65 and 85°C until analyzed for ß-oxidation activity. The protein concentration of the peroxisomal fractions was determined using Bio-Rad protein assay dye and BSA as a standard (Bradford, 1976).
Peroxisomal ß-oxidation evaluation.
ß-oxidation activity, a quantitative measurement of peroxisome proliferation, was determined using the method of Lazarow (1981). Briefly, the cyanide-insensitive ß-oxidation activity was measured using 5 µg hepatic peroxisomal protein/tube (0.5 mg protein/ml) and incubated at 37°C for 10 min with [14C]palmitoyl-CoA as the substrate. The reaction mixture contained 1 mM of potassium cyanide. The reaction was stopped by the addition of perchloric acid.
Statistical analyses.
Data were analyzed by one-way analysis of variance. When the corresponding F test for differences among test groups was significant, pairwise comparisons were made with the Dunnett's test (p < 0.05). The Bartlett's test for homogeneity of variance was also performed and if significant (p < 0.005), was followed by nonparametric procedures. Nonparametric procedures included the Kruskal-Wallis test for equal medians and the Mann-Whitney U test for pairwise comparisons (p < 0.05).
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RESULTS |
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DISCUSSION |
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Leydig Cell
Our early hypothesis for the mechanism of peroxisome proliferator-induced Leydig cell tumors was that this class of compounds increased peroxisomes in Leydig cells in a similar manner as in the liver (Cook et al., 1992). This hypothesis was based on the similarity between hepatocytes and Leydig cells; both have abundant smooth endoplasmic reticulum; however, hepatocytes utilize this organelle for xenobiotic metabolism while Leydig cells utilize it for steroid biosynthesis. In 2 strains of rat, WY did not induce peroxisomes in Leydig cells based upon biochemical (peroxisomal ß-oxidation activity) and electron microscopy (qualitative evaluation) criteria, at doses where abundant peroxisome induction was present in the liver (Biegel et al., 1992
; Hurtt et al., 1992). In the current study, C8 and WY did not induce peroxisomes in Leydig cells, as measured by peroxisomal ß-oxidation activity throughout the 2-year bioassay. These data demonstrate that peroxisome proliferators do not induce peroxisomes in Leydig cells, and hence, induce Leydig cell tumors via a different mechanism from that for liver tumors.
Early studies indicated that exposure to C8 and WY altered serum hormone concentrations. Surprisingly, in the current study, the only consistent alterations in serum hormone levels were an increase in estradiol concentrations and a mild decrease in prolactin concentrations; serum testosterone and LH concentrations were not significantly altered at the levels of C8 and WY that were tested. The Leydig cell tumors appear to be hormonally mediated where the sustained increase in estradiol, and possibly the decrease in prolactin concentrations, may play a key role. Both C8 and WY produced biologically significant increases in serum estradiol concentrations after 1 month of dietary administration. While the increases in the current study were not always statistically significant, there were numerical increases in estradiol concentrations at every time point, which were considered biologically significant. The only exception was in the WY animals at the 12 month time point, where estradiol concentrations were not increased. However, this was attributed to the reduction in the dietary concentration of WY from 50 to 25 ppm that occurred on test day 301. The increase in serum estradiol in the WY group was reestablished at the 15-month time point and was maintained through the remainder of the study.
We have proposed a mechanism for the induction of Leydig cell tumors where estradiol modulates growth factor expression in the testis to produce Leydig cell hyperplasia and neoplasia (Biegel, et al., 1995; Cook, et al., 1992
). Consistent with this hypothesis, WY produced approximately a 2-fold greater increase in the incidence of Leydig cell tumors than C8, and this correlated with the more sustained increase in estradiol that was observed in the WY-treated rats. In support of this hypothesis, it has been shown that administration of estradiol to mice produces Leydig cell tumors (Andervont et al., 1960
; Bonser, 1942
; Hooker and Pfeiffer, 1942
). In addition, it appears that human Leydig cell adenomas and the surrounding hyperplastic Leydig cells secrete large quantities of estradiol (Castle and Richardson, 1986
; Due et al., 1989
). In male rats, serum estradiol concentrations are maintained by the conversion of testosterone to estradiol via aromatase, a cytochrome P450 containing monooxygenase (Coffey, 1988
). It has been demonstrated that peroxisome proliferators increase serum estradiol levels via induction of aromatase (Biegel et al., 1995
, Liu et al., 1996a
,b
). This hepatic aromatase induction increases serum estradiol concentrations (Biegel, et al., 1995
; Cook, et al., 1992
; Liu et al., 1996a
,b
), which increases testis estradiol concentrations (Biegel, et al., 1995
). The increase in testicular estradiol concentrations (interstitial fluid) modulates growth factors, specifically TGF
, within the testis (Biegel, et al., 1995
).
Estradiol has been shown to stimulate the secretion of transforming growth factor (TGF-) by mammary epithelial cells and over expression of TGF
has been suggested as one possible factor in producing sustained cell proliferation of mammary tumor cells and the subsequent development of neoplasia (Liu et al., 1987
). TGF
binds to the EGF receptor and stimulates cell proliferation (reviewed in Moses et al., 1988). It is notable that TGF
stimulates thymidine incorporation into Leydig cell precursors and appears to be a Leydig cell stimulant (Khan et al., 1992a
). TGF
has been identified in Leydig cells (Teerds et al., 1990
). Hence, it is possible that the peroxisome proliferator-induced elevation of estradiol concentrations may be responsible for the development of Leydig cell adenomas. Studies with compounds that directly elevate serum estradiol concentrations (i.e., 17ß-estradiol) are necessary to fully investigate this hypothesis.
Conflicting evidence exists for the role of estrogens in the development of Leydig cell tumors in rats. Estrogenic compounds do not induce Leydig cell tumors in rats when given at doses which produce testicular atrophy, which can confound detection of Leydig cell hyperplasia (Gibson, et al., 1967; Marselos and Tomatis, 1992
; Schardein, 1980
; Schardein, et al., 1970
). These earlier studies were also limited by small sample size and reduced survival. Interestingly, GnRH agonists induce Leydig cell tumors at low doses, but do not induce Leydig cell tumors at higher doses where LH concentrations are suppressed and testicular atrophy occurs (Donaubauer et al., 1987; Hunter et al., 1982
; Physician's Desk Reference, 1995a
,b
,c
). Hence, these negative bioassays with estrogenic compounds may be due to suppression of LH, which to date is the primary demonstrated "driver" of Leydig cell tumors. Estradiol does appear to play a role in enhancement of Leydig cell tumorigenesis based on data from aging studies. In F344 rats, which have a high spontaneous incidence of Leydig cell tumors, there is an age-related increase in serum estradiol, which correlates with the development of Leydig cell hyperplasia and tumor formation (Turek and Desjardins, 1979
). However, in the CD rat, which has a low spontaneous incidence of Leydig cell tumors, serum estradiol decreases with age (Cook et al., 1994). In the current 2-year rat mechanistic bioassay, C8 and WY produced a sustained increase in serum estradiol concentrations that correlated with the potency of the 2 compounds to induce Leydig cell tumors. These studies suggest that estradiol may play a role in enhancement of Leydig cell tumors in the rat, and that peroxisome proliferators may induce Leydig cell tumors via a non-LH type mechanism. Whether estradiol plays a role in the induction of Leydig cell tumors by peroxisome proliferators can only be determined from an estradiol bioassay conducted at levels that do not induce testicular atrophy or reduce LH concentrations.
Pancreas
The development of pancreatic acinar cell tumors in the rat has been shown to be modified by several factors such as steroid concentrations (testosterone and estradiol), growth factors, cholecystokinin (CCK), and diet (fat) (Longnecker, 1983, 1987
; Longnecker and Sumi, 1990
). Castration, ovariectomy, and hormone replacement with estradiol and testosterone have been shown to influence the growth of carcinogen-induced preneoplastic foci in the azaserine-rat model of pancreatic carcinogenesis (Longnecker and Sumi, 1990
). The incidence of spontaneous and induced neoplasms of the exocrine pancreas is higher in male than in female rats. Additionally, growth factors such as CCK have been shown to stimulate normal, adaptive, and neoplastic growth of pancreatic acinar cells in rats. CCK is found in the gut mucosa and is released into the bloodstream in response to the presence of food in the duodenum. CCK then binds to receptors on the pancreatic acinar cells and stimulates release of pancreatic secretions into the gut. The pancreatic secretions contain the monitor peptide, a protein that binds to the receptors in the duodenum to stimulate CCK release into the bloodstream. Chymotrypsin is also found in pancreatic juice and is cleaved into trypsin inside the gut. Trypsin digests proteins present in the gut. Once there is no food present in the gut, trypsin degrades the monitor protein, which stops the further release of CCK. In the current 2-year study, WY produced approximately a 3.5-fold greater incidence of combined (i.e., adenoma and carcinoma) tumors than C8. The induction of pancreatic acinar cell tumors has also been reported for two other peroxisome-proliferating compounds, clofibrate and nafenopin (Physician's Desk Reference, 1996
; Reddy and Rao 1997a
,b
). Hence, the induction of these tumors also appears to be associated with this class of compounds. It has also been shown that a series of aliphatic dicarboxylic acids, which produce hypolipidemic activity, increase fecal fat content. Although Izydore and Hall (1991) did not examine whether these aliphatic dicarboxylic acids are peroxisome proliferators, the "substrate overload hypothesis" would indicate that the dicarboxylic acids are responsible for the induction of peroxisomes. If this is true, then aliphatic dicarboxylic acids are likely to be peroxisome proliferators. Hence the ability of C8 and WY to induce pancreatic acinar cell tumors may be due to increasing the fat content in the gut, presumably by enhanced excretion of cholesterol/triglycerides in the liver. The increased fat content in the intestine would increase CCK release into the bloodstream. The sustained increase in serum CCK would enhance pancreatic acinar cell hyperplasia and the eventual formation of adenomas. Data suggest that peroxisome proliferators such as C8 and WY increase CCK concentrations; this may play a key role in the induction of pancreatic tumors. This hypothesis was further investigated by Obourn and co-workers (1997), who found that the WY-induced cholestasis produced increased plasma concentrations of CCK. They hypothesized that the pancreatic acinar cell tumors were induced via a mild, yet sustained increase in plasma CCK, secondary to hepatic cholestasis.
Summary
In conclusion, the peroxisome proliferators WY and C8 both produced the tumor triad of hepatocellular, Leydig cell, and pancreatic acinar cell tumors in the 2-year mechanistic bioassay in CD rats. This data, in conjunction with previously published data for other peroxisome-proliferating compounds (Cook et al., 1992; Longnecker, 1983
; Malley et al., 1995
; Tucker and Orten, 1995; Physician's Desk Reference, 1996
; Reddy and Rao, 1997a
) supports the hypothesis that induction of this tumor triad is a common occurrence among peroxisome-proliferating compounds. Regarding the induction of pancreatic acinar cell tumors, current data suggests that peroxisome-proliferating compounds such as WY and C8 induce pancreatic acinar cell tumors via increased CCK concentrations; however, the primary driver of the increased CCK has not been elucidated (Obourn et al., 1997
). The data from the current study suggest that the induction of the Leydig cell tumors by peroxisome proliferators is a result of a sustained increase in serum estradiol concentrations. Interestingly, GnRH agonists induce Leydig cell tumors at low doses, but do not induce Leydig cell tumors at higher doses where LH concentrations are suppressed and testicular atrophy occurs (Donaubauer et al., 1987; Hunter et al., 1982
; Physician's Desk Reference, 1995a
,b
,c
). Hence, these negative bioassays with estrogenic compounds may be due to suppression of LH, which to date is the primary demonstrated "driver" of Leydig cell tumors. In the current 2-year rat mechanistic bioassay, C8 and WY produced a sustained increase in serum estradiol concentrations that correlated with the potency of the 2 compounds to induce Leydig cell tumors. These studies suggest that estradiol may play a role in enhancement of Leydig cell tumors in the rat, and that peroxisome proliferators may induce Leydig cell tumors via a non-LH type mechanism. Whether estradiol plays a role in the induction of Leydig cell tumors by peroxisome proliferators can only be determined from an estradiol bioassay conducted at levels that do not induce testicular atrophy or reduce LH concentrations.
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ACKNOWLEDGMENTS |
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NOTES |
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