Immunohistochemical study of cell proliferation, Bcl-2, p53, and caspase-3 expression on preneoplastic changes induced by cadmium and zinc chloride in the ventral rat prostate.

A R T I C L E

Immunohistochemical Study of Cell Proliferation, Bcl-2, p53,

and Caspase-3 Expression on Preneoplastic Changes Induced by

Cadmium and Zinc Chloride in the Ventral Rat Prostate

Ria´nsares Arriazu, Jose´ M. Pozuelo, Nuno Henriques-Gil, Teresa Perucho, Rocı´o Martı´n,

Rosario Rodrı´guez, and Luis Santamarı´a

Cell Biology and Histology Laboratory (RA,JMP,RR) and Genetics Laboratory (NH-G,TP), San Pablo–CEU University, Madrid, Spain; Service of Pathology, Hospital N. Sra. de Sonsoles, A´ vila, Spain (RM); and Department of Morphology, School of Medicine, Autonomous University of Madrid, Madrid, Spain (LS)

S U M M A R Y This work was directed to evaluate immunoexpression of markers for apo-ptosis, resistance to apoapo-ptosis, and cell proliferation, as well as estimates of nuclear size in ventral prostate of rats treated with cadmium chloride and cadmium 1 zinc chloride because a possible protective effect of zinc has been postulated. The following variables were studied: volume fraction (VF) of Bcl-2 immunostaining, percentage of cells immunoreactive to

proliferating cell nuclear antigen (LIPCNA) and p53 (LIp53), numerical density of caspase-3

immunoreactive cells (NVcaspase-3), and estimates of volume-weighted mean nuclear

vol-ume (yV). The LIPCNAand VFof Bcl-2 were significantly increased in the treated animals.

The dysplasias (independent of their origin) showed a significant increase of the LIp53, NV

caspase-3, and yVin comparison with normal acini from treated and control animals. It can

be concluded that cell proliferation is enhanced in long-term cadmium-exposed rats, and exposure to zinc combined with cadmium had no effect on any of the variables studied when comparing with normal acini. The increase of nuclear yVcould indicate a more aggressive

behavior for pretumoral lesions. (J Histochem Cytochem 54:981–990, 2006)

K E Y W O R D S rat prostate cadmium zinc dysplasia immunohistochemistry

PROSTATIC INTRAEPITHELIAL NEOPLASIA(PIN) is the

histo-logic change most commonly associated with prostate cancer and has been proposed as a precursor of invasive prostate cancer (Bostwick 1992,1996). A number of studies have concluded that high-grade PIN represents the most likely precursor to invasive adenocarcinoma (Marshall 2001; Nicholson and Theodorescu 2003).

Molecular and immunohistochemical markers have been found to be useful in characterizing the progres-sion of human PIN. These markers include changes in several genes that encode the expression of cell pro-liferation regulators (e.g., bcl-2, p53, p16, p22, and Cerb-B2) (Bostwick 1996; Bostwick et al. 1996; Martin et al. 2001; Nicholson and Theodorescu 2003).

Bcl-2 is a small intracellular non-glycosylated pro-tein that is able to inhibit the apoptotic pathway when overexpressed in cells (Knillova and Kolar 2003). p53 protein regulates cell-cycle inhibition and apoptosis in response to DNA damage, and mutated forms of p53 gene are commonly found in human cancers (Knillova and Kolar 2003; Sirvent et al. 2004). Cas-pases are aspartate-specific cysteine proteases existing as latent intracellular zymogens (O’Neill et al. 2001). They are fundamental components of the mammalian apoptotic machinery (Cohen 1997), but the precise contribution of individual caspases is controversial. Caspase-3 is one of the key executioners that becomes activated during apoptosis (Cohen 1997).

Some epidemiological and animal studies provide substantial evidence implicating cadmium, a known human carcinogen, as a prostate carcinogen (Waalkes 2000; Nakamura et al. 2002). It has been stated that cadmium chloride produces premalignant and/or inva-sive epithelial lesions in ventral rat prostate when ad-ministered in drinking water (Waalkes 2000; Martin

Correspondence to: L. Santamarı´a, Department of Morphology, School of Medicine, Autonomous University, C/Arzobispo Morcillo, 2, E-28029 Madrid, Spain. E-mail: luis.santamaria@uam.es

Received for publication May 17, 2005; accepted March 11, 2006 [DOI: 10.1369/jhc.5A6733.2006].

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C The Histochemical Society, Inc. 0022-1554/06/$3.30 981

et al. 2001). Zinc may have a relevant impact on cad-mium carcinogenesis. Because of the similarity in the transport characteristics between zinc and cadmium, it has been suggested that these metals share a common transport pathway (King et al. 1999; Waalkes 2000), and zinc treatments should reduce or abolish the adverse effects of cadmium, depending on the tissue and cir-cumstances (Waalkes 2000).

The main experimental model for human prostate cancer is the rat (Pollard and Wolter 2000; Shirai et al. 2000; Pollard et al. 2001; Morrissey et al. 2002), and morphological similarities between human PIN and dysplastic changes experimentally promoted in rodent prostate have been reported (Bosland 1999; Martin et al. 2001).

The aim of this study was to investigate (a) the pres-ence and morphology of preneoplastic lesions caused by exposure to cadmium and the influence of zinc on these lesions in rat prostate and (b) the immunohistochemical protein expression of apoptosis promoter and suppres-sor genes and cell proliferation.

Materials and Methods

Animals

Sixty male Sprague Dawley rats, 30 days old at the beginning of the study, were used for immunohistochemical and stereological studies. The animals were fed with Panlab Lab Chow (Barcelona, Spain) and water ad libitum. Animal pro-tocols are in compliance with the guidelines for the care and use of research animals adopted for the Society of Reproduc-tion. The animals were classified into three groups according to treatment (20 rats/group). Cadmium (Panreac; Madrid, Spain) was added to the drinking water of the first group at a concentration of 60 ppm during the time course of the ex-periment (24 months). The second group received zinc chlo-ride (Panreac) at a concentration of 50 ppm plus cadmium (60 ppm) in the drinking water. The third group was used as control and received drinking water free of these metals.

Five rats per treatment group were killed each 6 months until the end of the experiment (24 months). All animals were euthanized by exsanguination after CO2narcosis. Although

body weight at the end of the experiment was slightly higher in controls than in treated rats, no significant differences in the size of the animals were detected.

The prostate complex was dissected from the abdominal cavity of each animal. Dorsolateral prostate lobes were rou-tinely examined in all groups studied, and no dysplastic changes were detected. Only the ventral lobe was employed in the study. Afterwards, the ventral prostate was exhaustively sectioned into 2-mm-width slices. The section plane was per-pendicular to the sagittal axis of the gland. All specimens were fixed by immersion in 4% paraformaldehyde in PBS, pH 7.4, for 24 hr and afterwards embedded in paraffin.

Sampling Procedure

For each prostate, the slices obtained were embedded in a paraffin block. The blocks were serially sectioned, and

5-mm-thick sections (for immunohistochemistry and routine hema-toxylin–eosin staining) alternating with 10-mm-thick sections (for stereological cell counting) were obtained from each block. Ventral prostate was included in every section.

Evaluation of immunostainings was performed on five sections selected by random systematic sampling (Gundersen et al. 1988; Nevalainem et al. 1996) from each block obtained from each animal in each group for each immunostaining. Histologic Definition of the Lesions

Morphological criteria used for identifying the lesions as dys-plastic were (a) enlargement of the epithelial lining of the acinus usually associated with nuclear pseudostratification, (b) increase in the basophilic appearance of the epithelium with nuclear crowding, (c) nuclear pleomorphism, and (d) cribriform pattern.

Immunohistochemical Methods

In all groups, at least five selected slides per animal (per pros-tate) and per antigen were immunostained. Deparaffinized and rehydrated tissue sections were treated for 30 min with 0.3% hydrogen peroxide in phosphate-buffered saline (PBS), pH 7.4, to block endogenous peroxidase. To detect Bcl-2, p53, caspase-3, and proliferating cell nuclear antigen (PCNA) immunoreactivities, sections were incubated with the follow-ing monoclonal antibodies: anti-Bcl-2 antibody (1:10; Dako, Copenhagen, Denmark), anti-p53 antibody (1:50; Cell naling, Beverly, MA), anti-caspase-3 antibody (1:50; Cell Sig-naling), and anti-PCNA antibody (1:100; Biomeda, Foster City, CA). Pretreatment of sections by heating in citrate buffer, pH 6.0 (using a pressure cooker) (Martin et al. 2001), was performed to enhance Bcl-2, p53, and caspase-3 immuno-staining. All primary antisera were diluted in PBS, pH 7.4, containing 1% BSA (Merck; Darmstadt, Germany) plus 0.1% sodium azide. All incubations with primary antisera were done overnight at 4C. Secondary antibodies employed were biotin–caproyl anti-mouse immunoglobulins (Biomeda) di-luted 1:400 in PBS containing 1% BSA without sodium azide. All incubations with secondary antibodies were done for 30 min at room temperature. Thereafter, sections were treated with a streptavidin–biotin–peroxidase complex (Biomeda). The immunostaining reaction product was developed using 0.1 g diaminobenzidine (DAB) (3,39,4,49-tetraminobiphenyl; Sigma, St Louis, MO) in 200 ml of PBS plus 40 ml 30% hydrogen peroxide.

After immunoreactions, slides were counterstained with either acetic carmine, Harris hematoxylin, or methyl green, de-hydrated in ethanol, and mounted in a synthetic resin (Depex; Serva, Heidelberg, Germany). Specificity of the immuno-histochemical procedures was checked by incubation of sec-tions with non-immune serum instead of the primary antibody. Quantitative Evaluation of Cell Proliferation and p53 Percentages of PCNA-immunostained nuclei (PCNA labeling index, LIPCNA) (Martin et al. 2001; Arriazu et al. 2005a) and

p53-immunostained nuclei (p53 labeling index, LIp53) were

calculated in each selected section for control rats, non-dysplastic acini of treated rats, and non-dysplastic acini of treated animals, using the following formula: number of labeled nuclei 3 100/total number (labeled 1 unlabeled) of nuclei.

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Measurements were carried out using an Olympus (Hamburg, Germany) microscope equipped with a 3100 oil-immersion lens (numerical aperture 1.4) at a final magnification of 31200 and using the stereologic software GRID (Interactivision; Silkeborg, Denmark). This program allows the selection of fields to be studied by random systematic sampling after the input of an appropriate sampling fraction. An average of 100 fields per section was scanned, and a total of 500 epithelial nuclei were evaluated per section in each group (controls, non-dysplastic, or dysplastic) per animal. The systematic field selection with a random starting point (random systematic sampling method) assures that p53 and PCNA estimates were representative of all the prostate tissue (Martin et al. 2001; Arriazu et al. 2005a). p53- and PCNA-immunostained nuclei were considered positive regardless of staining intensity. Quantitative Evaluation of Bcl-2 Immunostaining To quantify the immunoreactivity of Bcl-2 protein, its volume fraction (VF) was measured and expressed as percentage of

immunostained epithelium. Estimation of the VF was

performed using the Scion Image Beta 4.02 program, avail-able at http://www.scioncorp.com/frames/fr_scion_products. htm. The systematic randomly selected fields were photo-graphed at a final magnification of 3500 and were then cap-tured by image program, thresholded, and binarized, and the percentage of epithelial area was automatically measured by the program to obtain the VF(Arriazu et al. 2005b). The VF

of Bcl-2 immunoreactivity was estimated in ventral prostates from control and experimental animals to ascertain if the treatment changes the total amount of Bcl-2 immunostaining in the epithelium. Bcl-2 was measured in each selected section from control rats, non-dysplastic acini of treated rats, and dysplastic acini of treated rats.

Evaluation of Numerical Cell Density

Estimation of the number of epithelial caspase-3-positive (caspase-3+) cells was performed using the optical dissector technique, an unbiased stereological method (Wreford 1995; Howard and Reed 1998). Three 10-mm-thick caspase-3 immunostained sections of control, treated, and dysplastic acini were chosen by systematic random sampling from each tissue block selected in each specimen. An average of 100 fields/section was systematically randomly sampled and used to count the number of cells by applying the GRID ste-reologic software. The amount of cells was evaluated as nu-merical density (NV), i.e., the number of epithelial caspase-3+

cells/mm3_{of epithelial acinar volume.}

Volume-Weighted Mean Nuclear Volume (yV)

Estimation of the nuclear yV was carried out on three

sys-tematically random sampled hematoxylin–eosin sections per slice in each study group using the stereologic software GRID. An average of 120 nuclei were point sampled per case because the number of nuclei to be estimated to obtain reliable results is considered within the range of 70–150 (Martin et al. 1999). All measurements were performed using an Olympus micro-scope equipped with a 3100 oil-immersion lens at a final magnification of 31200. The program used to evaluate the nuclear yVenables the generation of random test-line

direc-tions that were superimposed onto the microscopic images.

Nuclear intercepts can be measured along these test lines (Gundersen and Jensen 1985; Sorensen and Ottosen 1991). The length of nuclear intercepts (IO) was processed to obtain

pIO3/3, an unbiased estimate of nuclear yV independent of

nuclear shape, which because of point sampling emphasizes larger nuclei rather than smaller ones. In addition, esti-mates of nuclear yV combine information about the

three-dimensional nuclear size with knowledge of variability of nuclear size.

Statistical Analysis

For each parameter studied, mean 6 SD was calculated. Three analyses by ANOVA were performed to: (a) investigate the influence of addition of zinc over the quantitative parameter considered (controls, cadmium-exposed rats, and cadmium 1 zinc-treated rats); (b) evaluate differences among controls, dysplastic acini from cadmium-treated animals, and dysplastic acini from cadmium 1 zinc-exposed rats; and (c) investigate changes in acini from treated and non-treated groups and normal/dysplastic changes within groups. Comparison be-tween each pair of means was performed using the Student– Newmann–Keuls test; p,0.05 was considered significant.

To evaluate differences between age groups independent of the treatment (6 months, .6 months), Student’s t-test was used; p,0.05 was considered significant.

Results

Histological Findings

Fifteen dysplastic focal lesions were detected at the end of the experiment in the acinar epithelium of ventral prostate from cases treated with cadmium alone (six rats) and eight dysplastic focal lesions were detected in animals treated with cadmium 1 zinc (five rats). The acini from the controls showed a columnar mono-stratified epithelium (Figures 1A and 1B), whereas the dysplastic acini showed an irregularly enlarged epi-thelial lining (Figures 1C and 1D). The first dysplastic changes appeared after 12 months of treatment and are early, isolated, and small lesions (Figure 1C), whereas those appearing at 24 months are larger. Distribution of the dysplastic acini of long evolution was multicentric for the group of cadmium-exposed rats and single for the cadmium 1 zinc-treated animals. The non-dysplastic acini from treated rats had a similar morphology to that of the acini of control rats. In comparison with control acini, dysplastic glands showed a remarkable enlarge-ment with frequent cribriform pattern (Figures 1C and 1D). Occasional polypoid formations were seen. The nuclei presented important size heterogeneity, and nu-cleoli were usually prominent (Figure 1D). Occasional mitosis was observed (Figure 1D). No tumoral infiltra-tion in the surrounding stroma was demonstrated. PCNA and p53 Immunostaining

PCNA immunostaining has been detected in the nu-clei from all specimens studied (Figures 2A and 2B).

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Dysplastic acini showed remarkable immunoreactivity to PCNA in comparison with controls (Figure 2C).

Immunoreactivity to p53 was detected in both cytoplasm and nucleus of epithelial cells from prostate acini throughout all groups (Figures 2D and 2E). Nu-clear p53 immunostaining was also remarkable in the acini with dysplastic changes (Figure 2F).

Bcl-2 and Caspase-3 Immunostaining

Immunoreactivity to Bcl-2 protein was observed in all groups of rats. It was granular and expressed in the apical border of the epithelium in controls and non-dysplastic acini (Figures 2G and 2H). Bcl-2 immuno-staining was more widely distributed throughout the cytoplasm in dysplastic glands but was more prominent near the lumen of the cribriform structures (Figure 2I).

Immunostaining to caspase-3 was not detected in the prostate epithelium of controls (Figure 2J). Caspase-3 immunoreactivity was observed in the cytoplasm from isolated epithelial cells and was frequent in those cells detached to the lumen of the acinus. This immuno-reactivity was occasionally shown in the non-dysplastic epithelium from treated rats (Figure 2K) and remark-ably increased in the dyplastic lesions (Figure 2L). Quantitative Results

Significance of ANOVA carried out to evidence in-fluence of the type of treatment on the quantitative parameters is shown in Table 1. A significant increase for the LIPCNAand VFBcl-2 occurs in both

cadmium-and cadmium 1 zinc-treated animals when compared with the controls. No significant differences were

Figure 1 Hematoxylin–eosin staining of ventral prostate from control and rats exposed to metals. (A) Control rat (6 months). The epithelial lining of the acini located at the periphery of this region (asterisks) is taller than the subjacent acini (stars). Most of the epithelial cell nuclei are arranged in monostratified layers in both types of acini. (B) Detail from A. The epithelium of peripheral acini is columnar monostratified with basal nuclei (black arrowhead) and with occasional pseudostratification of nuclei (white arrowhead). (C) Small lesion showing intense dysplasia (arrowhead) in the ventral prostate of a rat treated for 18 months with cadmium 1 zinc. Cribriform structures are visualized (star). (D) Dysplastic acini of an animal treated for 24 months with cadmium chloride. The nuclei presented heterogeneous size (arrowheads) and prominent nucleoli (arrow). A cribriform pattern (stars) and mitosis were observed (white arrowheads). Original magnification: A,C 5 3100; B,D 5 3400.

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Figure 2 (A) A representative acini from an 18-month-old control animal immunostained to proliferating cell nuclear antigen (PCNA). Immunoreactive nuclei are observed in the epithelium (arrowheads). (B) PCNA immunostained non-dysplastic acini of a rat treated for 18 months with cadmium chloride 1 zinc chloride showing some immunoreactive nuclei (arrowheads). (C) PCNA-immunostained dysplastic acini of cadmium-exposed rat. Many PCNA-positive nuclei are observed (arrowheads). (D) p53-immunostained acini of a 6-month-old control rat. Immunoreactive nuclei (black arrowheads) and cytoplasm (white arrowheads) are detected in the epithelium. (E) p53-immunostained non-dysplastic acini from a rat exposed to cadmium chloride for 12 months. There are immunopositive nuclei (black arrowheads) and cytoplasm (white arrowheads). (F) p53-immunostained dysplastic acini of a rat exposed to cadmium 1 zinc for 24 months. There are immunopositive nuclei in the epithelium (arrowheads). (G) Immunostaining to Bcl-2 protein in an 18-month-old control acinus. Granular immunoreactivity is observed in apical border of epithelium (arrowheads). (H) Immunostaining to Bcl-2 protein in a non-dysplastic acinus from a 24-month-old cadmium 1 zinc-treated rat. Localization of immunoreactivity is similar to that observed in controls (arrowheads). (I) Immunostaining to Bcl-2 protein in a dysplastic acinus from a 24-month-old cadmium-chloride-treated rat. Immunoreactivity is observed in the apical border of epithelium (arrowheads). (J) No immunoreactivity for caspase-3 is observed in control acini from a 6-month-old rat. (K) One isolated cell immunoreactive to caspase-3 was observed in the epithelium (arrowhead) from a 6-month-old cadmium-chloride-exposed rat. (L) Caspase-3 immunostaining in a dysplastic acinus from a 24-month-old cadmium-chloride-exposed rat. Some isolated epithelial cells show immunoreactivity (arrowheads). Original magnification: A–L 3400.

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observed between treatment types (Figures 3A and 3B). Nuclear yVdid not show significant differences between

treatment types, but the cadmium-exposed rats showed a significant increase in this parameter in comparison to controls (Figure 3C).

ANOVA results regarding the influence of the type of dysplasias according to their origin (cadmium- or cadmium 1 zinc-exposed rats) are also shown in Table 1. LIPCNAshowed a significant increase in the dysplasias

in comparison with control acini. The two treatment groups showed no significant differences (Figure 4A). For LIp53, no significant differences between types of

dysplasias could be detected, but the dysplasias caused by cadmium exposure showed a significant increase of LIp53in comparison with the controls (Figure 4B).

However, when the numerical density for caspase-31 cells was considered, this parameter showed a signifi-cant increase in the dysplasias. Dysplastic regions from both treatment groups displayed no significant differ-ences. No significant differences were also observed be-tween the sources of dysplasias (Figure 4C). Nuclear yVshowed a significant increase in both cadmium and

cadmium 1 zinc dysplasias when compared with con-trols. No significant differences were ascertained be-tween the sources of dysplasias (Figure 4D).

When the two types of dysplastic lesions were con-sidered as a whole, LIPCNA was significantly increased

in both treated non-dysplastic and dysplastic acini when compared with controls. Nevertheless, no signifi-cant differences were observed between treated non-dysplastic and non-dysplastic glands (Figure 5A).

There was a significant increase in the VF Bcl-2 in

dysplastic acini when compared with controls, but no differences were observed between treated non-dysplastic and non-dysplastic glands (Figure 5B).

LIp53and the numerical density for caspase-31 cells

were significantly increased in dysplastic acini in com-parison with controls and treated non-dysplastic acini (Figures 5C and 5D).

There was a significant increase in nuclear yVfrom

dysplastic acini, in comparison with both controls and treated non-dysplastic acini (Figure 6).

The significance of Student’s t-test carried out to as-certain influence of the time of exposure to the treat-ment is shown in Table 2. Significant differences were detected only for LIPCNA. A significant increase was

also observed for the LIPCNA of animals treated for

.6 months (Figure 7).

No significant histologic lesions were observed during the first 6 months of treatment with cadmium chloride. These results are in accordance with the find-ings of Visser and Dekler (1979), who reported no sig-nificant changes in the rat prostate epithelium after 6 and 10 months of cadmium treatment. In the speci-mens treated for 12 and 18 months with cadmium or

Table 1 Significance of ANOVAs carried out to investigate the influence of treatments (p treatment) and the influence of the type of dysplastic acini according to their origin (cadmium or cadmium 1 zinc) ( p dysplastic acini)

Variable p (treatment) p (dysplastic acini)

LIPCNAa 0.0152 0.0003 VFBcl-2b 0.0120 0.0573 LIp53c 0.1042 0.0129 NVcaspase-31 cellsd 0.5628 0.0002 Nuclear yVe 0.0381 ,0.0001 a_LI

PCNA, labeling index for PCNA. b_V

FBcl-2, volume fraction of Bcl-2. c_LI

p53, labeling index for p53. d_N

Vcaspase-31 cells, numerical density of caspase-3-positive cells (number of

caspase-3-positive cells/mm3_{of epithelial acinar volume).} e_{nuclear y}

V, volume-weighted mean nuclear volume.

p,0.05 was considered significant.

Figure 3 Bar graphs for LIPCNA(A), volume fraction of Bcl-2 (B), and

volume-weighted mean nuclear volume (C). Measurements corre-spond to controls (ctrls), rats exposed to cadmium (cd), and rats exposed to cadmium 1 zinc (cd1zn). Results are expressed as mean 6SD. Bars showing different numbers at the top of the error bars differ significantly (p,0.05).

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cadmium 1 zinc, structural alterations observed were considered as preneoplastic lesions by several authors (Parkinson 1995; Bostwick et al. 1996). Evident mor-phological changes (dysplasia) were observed in the present study in prostate acini after 24 months of cad-mium and cadcad-mium 1 zinc exposure, and these results confirm the carcinogenic effects of cadmium (Shirai et al. 1993; Waalkes 2000). Our results suggest that the oral administration of zinc might reduce the occur-rence of dysplastic changes mediated by cadmium. The isolate character of the appearance of the lesions in rats treated with zinc, in comparison to the multifocal dys-plasias observed in animals exposed to cadmium alone, could indicate a lesser aggressiveness when zinc was added. It has been demonstrated that prostate

epi-thelium is able to concentrate zinc, and this metal could inhibit the growth of prostate cells (Costello and Franklin 2000; Feng et al. 2000).

The significant increase of cell proliferation observed in the groups treated .6 months might be due to the growth of dysplasias from 12 months of exposure (Waalkes et al. 1992). No other significant changes have been observed between rats with 6 months of treat-ment and animals with .6 months of exposure.

According to some authors (King et al. 1999; Waalkes 2000), zinc treatment should reduce or abolish the adverse effects of cadmium, given the similarity in the transport characteristics between both metals. Nevertheless, when all the acini excluding the dys-plastic ones were considered, exposure to zinc combined

Figure 4 Bar graphs for LIPCNA(A),

LIp53 (B), numerical cell density for

caspase-3-positive (caspase-31) cells (C), and volume-weighted mean nu-clear volume (D). Measurements cor-respond to controls (ctrls), dysplasias mediated by cadmium (Disp cd), and dysplasias mediated by cadmium 1 zinc (Disp cd1zn). Results are ex-pressed as mean 6 SD. Bars showing different numbers at the top of the error bars differ significantly (p,0.05).

Figure 5 Bar graphs for LIPCNA(A),

volume fraction of Bcl-2 (B), LIp53(C),

and numerical cell density for caspase-31 cells (D). Measurements correspond to controls (ctrls), non-dysplastic acini from both types of exposed rats (trea-ted), and dysplastic acini from both types of exposed rats (dysplasia). Re-sults are expressed as mean 6 SD. Bars showing different numbers at the top of the error bars differ significantly (p,0.05).

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with cadmium had no effect over any of the variables studied. Although LIPCNAand VFBcl-2 were increased

in rats exposed to cadmium or cadmium 1 zinc in com-parison with untreated animals, the differences were not significant, in contrast to those observed in other studies (Martin et al. 2001). According to the low ex-pression of Bcl-2 protein, there were no differences in the single-strand conformation analysis (SSCA)-band pattern of bcl-2 gene in all the animals (data not shown), indicating that the mutation rate is apparently not af-fected by the treatments assayed. A number of studies have analyzed the p53 expression in human prostate (Downing et al. 2003; Zeng et al. 2004); however, p53 expression is not well documented in rat prostate epi-thelium. Immunoreactivity to p53 visualized in ventral prostate in this study did not show changes in relation to the different groups of treatment; however, the PCR-SSCA study revealed a new band in one rat treated with cadmium 1 zinc for 6 months (data not shown). This band appears as a consequence of the conformational change of single strands as suggested by Sheffield et al. (1993), in this case a substitution of adenine by guanine

as a normal single nucleotide polymorphism not detected until now at this point of the p53 gene in the rat genome.

For the first time, caspase-3 immunoexpression has been detected in the ventral prostate from rats, involving an increase (independent of the zinc intake) of caspase-3 immunoreactive cell density in dysplastic acini. This finding does not agree with that observed in man, where caspase-3 expression is decreased in prostate cancer (O’Neill et al. 2001; Winter et al. 2001).

Cell proliferation was clearly increased in dysplastic acini, independently of the presence of zinc. It seems that, when the dysplastic changes are present in the cadmium-exposed acini, the proliferation rate is equal to that observed in cadmium 1 zinc-exposed glands, as indicated in a previous study (Arriazu et al. 2005a). LIp53is dependent on the presence of zinc, which could

be related to the binding of zinc by p53 protein, pro-moting the interaction between DNA and p53 and, consequently, the cell-cycle arrest after DNA damage (Achanzar et al. 2001).

When exposure to metals is prolonged, some focal areas of the epithelium undergo transformation, result-ing in upregulation of Bcl-2 expression, which produces an increase in focal resistance to programmed cell death. This increase, together with the proliferation, may induce the progression of these areas toward dys-plasia, as has been postulated for human PIN (Martin et al. 2001).

Differences in the expression and localization of PCNA and Bcl-2 between rat and human prostates are remarkably pronounced. In normal human prostate, the proliferation compartment (the basal layer, PCNA, and Bcl-2 positive) is better defined than in rat prostate where the basal compartment is represented by isolated cells and often absent in some portions of the acini. Moreover, proliferative activity in the rat is not

con-Figure 6 Bar graphs for volume-weighted mean nuclear volume. Measurements correspond to controls (ctrls), non-dysplastic acini from both types of exposed rats (treated), and dysplastic acini from both types of exposed rats (dysplasia). Results are expressed as mean 6SD. Bars showing different numbers at the top of the error bars differ significantly ( p,0.05).

Table 2 Significance of Student’s t-test carried out to investigate the influence of exposure time to the treatment ( p 6 months, .6 months)

Variable p (6 months, .6 months)

LIPCNAa 0.0002

VFBcl-2b 0.6771

LIp53c 0.1906

NVcaspase-31 cellsd 0.1644

a_LI

PCNA, labeling index for PCNA. b_V

FBcl-2, volume fraction of Bcl-2. c_LI

p53, labeling index for p53. d_N

V31 cells, numerical density of 31 cells (number of

caspase-31 cells/mm3_{of epithelial acinar volume).}

p,0.05 was considered significant.

Figure 7 Bar graphs for LIPCNAfor specimens of 6 months (six) and

.6 months (more than six). Results are expressed as mean 6 SD. Bars showing different numbers at the top of the error bars differ significantly ( p,0.05).

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fined to the basal cells. It has been reported that the main proliferating cells in rat prostate are the columnar (luminal) cells (Sensibar 1995).

There is an inverse relationship between volume fraction of Bcl-2 and the numerical density of caspase-3 immunoreactive cells in both control and exposed rats. This supports the results of Munshi et al. (2001), who indicated that the increase of Bcl-2 expression caused the decrease of caspase-3 activity. However, the sig-nificant increase of LIp53and NVcaspase-3 detected in

the dysplastic acini may be related to an increase in apoptotic activity, as described by Montironi et al. (1994) in human PIN.

Several neoplastic conditions in man (Martin et al. 1999) including prostate cancer (Fujikawa et al. 1995; Arai et al. 2001; Fischer et al. 2004) show an increase of nuclear yV that could indicate a more aggressive

be-havior for these lesions. In the present study, a signifi-cant increase of nuclear yV has been detected in rats

exposed to cadmium and in the dysplastic tissue, in-dependently of the treatment group. The change in nuclear size of dysplastic lesions may be a good marker of tumoral progression and could be correlated to the molecular and immunohistochemical changes observed in the evolution from normal to dysplastic epithelium (Bostwick 1996; Fischer et al. 2004).

We conclude that (a) a significant increase of cell proliferation occurs in animals treated with cadmium or cadmium 1 zinc for .6 months, (b) the exposure to zinc combined with cadmium had no effect over any of the variables studied when comparing with normal acini, (c) the increase of apoptosis in the dysplastic lesions was evident by the increment (independent of the zinc intake) of caspase-3 immunoreactive cell den-sity, and (d) the increase of nuclear yVis indicative of

a more aggressive behavior for pretumoral lesions. Acknowledgments

This work was supported in part by grants 9/01 and 9/03 of the Universidad San Pablo–CEU.

Literature Cited

Achanzar WE, Diwan BA, Liu J, Quader ST, Webber MM, Waalkes MP (2001) Cadmium-induced malignant transformation of human prostate epithelial cells. Cancer Res 61:455–458 Arai Y, Okubo K, Terada N, Matsuta Y, Egawa S, Kuwao S, Ogura K

(2001) Volume-weighted mean nuclear volume predicts tumor biology of clinically organ-confined prostate cancer. Prostate 46: 134–141

Arriazu R, Pozuelo JM, Martin R, Rodriguez R, Santamaria L (2005a) Quantitative and immunohistochemical evaluation of PCNA, androgen receptor, apoptosis and glutathione-S-transfer-ase P1 on preneoplastic changes induced by cadmium and zinc chloride in the rat ventral prostate. Prostate 63:347–357 Arriazu R, Pozuelo JM, Rodriguez R, Henriques-Gil N, Perucho T,

Martin R, Santamaria L (2005b) Cadmium and zinc chloride-induced preneoplastic changes in the rat ventral prostate: an immunohistochemical and molecular study. In Li JJ, Li SA, and

Llombart-Bosch A, eds. Hormonal Carcinogenesis IV. New York, Springer, 522–528

Bosland MC (1999) Use of animal models in defining efficacy of chemoprevention agents against prostate cancer. Eur Urol 35: 459–463

Bostwick DG (1992) Prostatic intraepithelial neoplasia (PIN): current concepts. J Cell Biochem Suppl 16:10–19

Bostwick DG (1996) Progression of prostatic intraepithelial neoplasia to early invasive adenocarcinoma. Eur Urol 30:145–152 Bostwick DG, Pacelli A, Lopez-Beltran A (1996) Molecular biology of

prostatic intraepithelial neoplasia. Prostate 29:117–134

Cohen GM (1997) Caspases: the executioners of apoptosis. Biochem J 326:1–16

Costello LC, Franklin RB (2000) The intermediary metabolism of the prostate: a key to understanding the pathogenesis and progression of the prostate malignancy. Oncology 59:269–282

Downing SR, Russell PJ, Jackson P (2003) Alterations of p53 are common in early stage prostate cancer. Can J Urol 10:1924–1933 Feng P, Liang JY, Li TL, Guan ZX, Zou J, Franklin R, Costello LC (2000) Zinc induces mitochondria apoptogenesis in prostate cells. Mol Urol 4:31–36

Fischer AH, Bardarov S Jr, Jiang Z (2004) Molecular aspects of diagnostic nucleolar and nuclear envelope changes in prostate cancer. J Cell Biochem 91:170–184

Fujikawa K, Sasaki M, Aoyama T, Itoh T, Yoshida O (1995) Prog-nostic criteria in patients with prostate cancer: correlation with volume weighted mean nuclear volume. J Urol 154:2123–2127 Gundersen HJ, Bendtsen TF, Korbo L, Marcussen N, Moller A,

Nielsen K, Nyengaard JR, et al. (1988) Some new, simple and ef-ficient stereological methods and their use in pathological research and diagnosis. APMIS 96:379–394

Gundersen HJ, Jensen EB (1985) Stereological estimation of the volume-weighted mean volume of arbitrary particles observed on random sections. J Microsc 138:127–142

Howard CV, Reed MG (1998) Number estimation. In Howard CV, Reed MG, eds. Unbiased Stereology. Three-Dimensional Measure-ment in Microscopy. Oxford, Bios Scientific Publishers, 69–105 King LM, Banks WA, George WJ (1999) Differences in cadmium

transport to the testis, epididymis, and brain in cadmium-sensitive and -resistant murine strains 129/J and A/J. J Pharmacol Exp Ther 289:825–830

Knillova J, Kolar Z (2003) The significance of key regulators of apoptosis in the development and prognosis of prostate carcinoma. I. Proteins of the Bcl-2 family and protein p53. Biomed Pap Med Fac Univ Palacky Olomouc Czech Repub 147:3–10

Marshall JR (2001) High-grade prostatic intraepithelial neoplasia as an exposure biomarker for prostate cancer chemoprevention re-search. IARC Sci Publ 154:191–198

Martin JJ, Martin R, Codesal J, Fraile B, Paniagua R, Santamaria L (2001) Cadmium chloride-induced dysplastic changes in the ventral rat prostate: an immunohistochemical and quantitative study. Prostate 46:11–20

Martin R, Sneige N, Vasquez M, Aragon-Flores M, Martin G, Marron C, Santamaria L (1999) Stereologic estimates of volume-weighted mean nuclear volume in aspiration smears of ductal breast carcinoma. Correlation with cytologic grade, tumor size and lymph node status. Anal Quant Cytol Histol 21:185–193 Montironi R, Magi-Galluzzi C, Marina S, Diamanti L (1994)

Quantitative characterization of the frequency and location of cell proliferation and death in prostate pathology. J Cell Biochem Suppl 19:238–245

Morrissey C, Buser A, Scolaro J, O’Sullivan J, Moquin A, Tennis-wood M (2002) Changes in hormone sensitivity in the ventral prostate of aging Sprague-Dawley rats. J Androl 23:341–351 Munshi A, Pappas G, Honda T, McDonnell TJ, Younes A, Li Y,

Meyn RE (2001) TRAIL (APO-2L) induces apoptosis in human prostate cancer cells that is inhibitable by Bcl-2. Oncogene 20: 3757–3765

Nakamura K, Yasunaga Y, Ko D, Xu LL, Moul JW, Peehl DM, Srivastava S, et al. (2002) Cadmium-induced neoplastic transfor-mation of human prostate epithelial cells. Int J Oncol 3:543–547

The

Journal

o

f

Histochemistry

&

Cytochemistry

Nevalainem MT, Valve EM, Ingleton PM, Harko¨nen PL (1996) Expression and hormone regulation of prolactin receptors in rat dorsal and lateral prostate. Endocrinology 137:3078–3088 Nicholson B, Theodorescu D (2003) Molecular therapeutics in

prostate cancer. Histol Histopathol 18:275–298

O’Neill AJ, Boran SA, O’Keane C, Coffey RN, Hegarty NJ, Hegarty P, Gaffney EF, et al. (2001) Caspase 3 expression in benign pros-tatic hyperplasia and prostate carcinoma. Prostate 47:183–188 Parkinson MC (1995) Pre-neoplastic lesions of the prostate.

Histo-pathology 27:301–311

Pollard M, Wolter W (2000) Prevention of spontaneous prostate-related cancer in Lobund-Wistar rats by a soy protein isolate/ isoflavone diet. Prostate 45:101–105

Pollard M, Wolter W, Sun L (2001) Diet and the duration of testosterone-dependent prostate cancer in Lobund-Wistar rats. Cancer Lett 173:127–131

Sensibar JA (1995) Analysis of cell death and cell proliferation in embryonic stages, normal adult, and aging prostates in human and animals. Microsc Res Tech 30:342–350

Sheffield VC, Beck JS, Kwitek AE, Sandstrom DW, Stone EM (1993) The sensitivity of single-strand conformation polymorphism analysis for the detection of single base substitutions. Genomics 16:325–332

Shirai T, Iwasaki S, Masui T, Mori T, Kato T, Ito N (1993) Enhancing effect of cadmium on rat ventral prostate carcinogenesis induced by 3,29-dimethyl-4-aminobiphenyl. Jpn J Cancer Res 84:1023–1030 Shirai T, Takahashi S, Cui L, Futakuchi M, Kato K, Tamano S, Imaida

K (2000) Experimental prostate carcinogenesis—rodent models. Mutat Res 462:219–226

Sirvent JJ, Aguilar MC, Olona M, Pelegri A, Blazquez S, Gutierrez C (2004) Prognostic value of apoptosis in breast cancer (pT1-pT2). A TUNEL, p53, bcl-2, bag-1 and Bax immunohistochemical study. Histol Histopathol 19:759–770

Sorensen FB, Ottosen PD (1991) Stereological estimation of nuclear volume in benign and malignant melanocytic lesions of the skin. Inter- and intraobserver variability of malignancy grading. Am J Dermatopathol 13:99–107

Visser AJ, Deklerk JN (1978) The effect of dietary cadmium on prostate growth. Trans Am Assoc Genitourin Surg 70:66–68 Waalkes MP (2000) Cadmium carcinogenesis in review. J Inorg

Biochem 79:241–244

Waalkes MP, Coogan TP, Barter RA (1992) Toxicological principles of metal carcinogenesis with special emphasis on cadmium. Crit Rev Toxicol 22:175–201

Winter RN, Kramer A, Borkowski A, Kyprianou N (2001) Loss of caspase-1 and caspase-3 protein expression in human prostate cancer. Cancer Res 61:1227–1232

Wreford NG (1995) Theory and practice of stereological techniques applied to the estimation of cell number and nuclear volume in the testis. Microsc Res Tech 32:423–436

Zeng L, Rowland RG, Lele SM, Kyprianou N (2004) Apoptosis incidence and protein expression of p53, TGF-b receptor II, p27Kip1_{, and Smad4 in benign, premalignant, and malignant}

human prostate. Hum Pathol 35:290–297

The

Journal

o

f

Histochemistry

&

Cytochemistry