RPMI-1640 medium, Ham’s F12 medium, fetal bovine serum (FBS) (mycoplasma-free), penicillin/streptomycin and trypsin were purchased from PAA Laboratories GmbH (Pasching, Austria). PBS was purchased from Invitrogen Corp. (Carlsbad, CA, USA). Ethylenediaminetetraacetic acid (EDTA), zinc(II) sulphate (BioReagent grade, suitable for cell cultures), RIPA buffer and all other chemicals of ACS purity were purchased from Sigma-Aldrich Co. (St. Louis, MO, USA), unless noted otherwise.

Two human prostatic cell lines were used in this study: a) PNT1A human cell line established by immortalisation of normal adult prostatic epithelial cells by transfection with a plasmid containing SV40 genome with a defective replication origin; the primary culture was obtained from the normal prostatic tissue of a 35-year old male at post mortem, and b) 22Rv1 human cell line derived from a xenograft that was serially propagated in mice after castration. Both cell lines used in this study were purchased from HPA Culture Collections (Salisbury, UK).

PNT1A cells were cultured in RPMI-1640 medium supplemented by 10% FBS. 22Rv1 cells were cultured in RPMI-1640 without phenol red (medium) with 10% FBS. The media were supplemented with penicillin (100 U/ml) and streptomycin (0.1 mg/ml), and the cells were maintained at 37°C in a humidified (60%) incubator with 5% CO₂ (Sanyo, Japan). The passages of PNT1A and 22Rv1 cell lines ranged from 10 to 35 h.

Immediately the cells grew up to 50-60% confluence, the cultivation media were replaced by a fresh medium to synchronize cell growth. Cells were cultivated under these conditions for 24 h, then cells were treated with zinc(II) sulphate (0-100 μM for both cell lines) dissolved in fresh medium for 48 h.

High pure total RNA isolation kit (Roche, Basel, Switzerland) was used for RNA isolation. Briefly, cultivation medium was removed and samples were washed twice with 5 ml of ice-cold PBS. Cells were transferred to clean tubes and centrifuged at 15,000 × g for 5 min at 4°C. After it, lysis buffer was added and RNA isolation was carried out according to the manufacturer’s instructions. Isolated RNA was used for cDNA construction. Total RNA (600 ng) was transcribed using transcriptor first strand cDNA synthesis kit (Roche). Prepared cDNA (20 μl) was diluted with RNase-free water to 100 μl and directly analysed by real-time polymerase chain reaction.

RT-PCR was performed in triplicates using the TaqMan gene expression assay with 7500 real-time PCR system (Applied Biosystems, Foster City, CA, USA). The amplified DNA was analysed by the comparative Ct method using β-actin as an endogenous control. The primer and probe sets for β-actin (assay ID: Hs00185826_m1), Fos (assay ID: Hs00170630_m1), c-Jun (assay ID: Hs00277190_m1), NF-κB (assay ID: Hs00765730_m1), p53 (assay ID: Hs01034649_m1), Bcl-2 (assay ID: Hs99999018_m1) were selected from TaqMan gene expression assay. Real-time PCR was performed under following amplification conditions: total volume of 20 μl, initial denaturation 95°C/10 min, then 40 cycles 95°C/15 sec, 60°C/1 min.

Total cell content was analysed using semi-automated image-based cell analyser (Cedex XS, Innovatis, Roche, Basel, Switzerland) according to the following protocol. Cultivation medium was removed and samples were two times washed with 5 ml of ice-cold PBS to maintain only viable cells. Cells were scraped and transferred to clean tubes. Trypan blue solution (Innovatis) was diluted to 0.2% prior to use and added to samples. Following settings were used in operating software: cell type: standard cells, dilution: none, process type: standard. All samples were measured in duplicates.

MTT assay was used to determine cell viability. The suspension of cells was diluted to the density of 5,000 cells/ml in the cultivation medium. Volume of 200 μl was transferred to 2-11 wells of standard microtiter plates. Medium (200 μl) was added to the first and to the last column (1 and 12, control). Plates were incubated for 2 days at 37°C to ensure cell growth under the same conditions described in Cell cultivation. Medium was removed from columns 2 to 11. Columns 3-10 were filled with 200 μl of medium containing increasing concentration of zinc(II) (0, 50, 100, 150, 200, 250, 300 and 500 μM). As control, columns 2 and 11 were not filled with medium containing zinc(II) ions. Plates were incubated for 24 h; then, media were removed and replaced by a fresh medium, three times a day. Columns 1 to 11 were filled with 200 μl of medium containing 50 μl of MTT (5 mg/ml in PBS) and incubated in a humidified atmosphere for 4 h at 37°C, wrapped in aluminium foil. After the incubation, MTT-containing medium was replaced by 200 μl of 99.9% dimethyl sulphoxide (DMSO) to dissolve MTT-formazan crystals. Then, 25 μl of glycine buffer was added to all wells and absorbance was immediately determined at 570 nm (VersaMax microplate reader, Molecular Devices, Sunnyvale, CA, USA).

The xCELLigence system (Roche Applied Science and ACEA Biosciences, San Diego, CA, USA) consists of four main components: the RTCA analyser, the RTCA DP station, the RTCA computer with integrated software and disposable E-plate 16. Firstly, the optimal seeding concentration for proliferation and cytotoxic assay was determined. After seeding the total number of cells in 200 μl medium to each well in E-plate 16, the attachment, proliferation and spreading of the cells was monitored every 15 min. All experiments were carried out for 250 h. The results are expressed as relative impedance using the manufacturer’s software (Roche Applied Science and ACEA Biosciences).

Software Statistica 10 (StatSoft Inc., Tulsa, OK, USA) was used for statistical analysis. Student’s t-test for independent values was used to evaluate differences between two groups. Simple linear correlations were performed to reveal the relationships between variables. Unless noted otherwise, a level of statistical significance was set at p<0.05.

For fluorescence microscopy, cells were cultivated directly on microscope glass slides (75×25 mm, thickness 1 mm, Fischer Scientific, Pardubice, Czech Republic) in Petri dishes in above-described cultivation media (see Cultured cell conditions). Cells were transferred directly onto slides, which were submerged in cultivation media. After treatment, microscope glass slides with monolayer of cells were removed from Petri dishes, rinsed with cultivation medium without zinc(II) supplementation and PBS buffer and directly used for staining and fluorescence microscopy.

For the staining of free thiols, respectively free -SH groups, 5-(bromomethyl)fluorescein (5-BMF, Sigma-Aldrich) was used. This probe reacts more slowly with thiols of peptides, proteins and thiolated nucleic acids in comparison with other fluorescent probes. However, it forms stronger thioether bonds that are expected to remain stable under the conditions required for fluorescence microscopy. Stock solution of 5-BMF (4 mM, anhydrous DMSO) was prepared prior to staining because of 5-BMF stability. Working solution was prepared immediately using stock solution by diluting to final concentration of 20 μM (PBS buffer, pH 7.6). Cells were incubated for 1 h at 37°C and in dark. Then, cells on microscope glass slide were three times washed by PBS buffer (pH 7.6) and observed using fluorescence microscope (Axioskop 40, Carl Zeiss AG, Oberkochen, Germany) equipped with wideband excitation and set of filters (FITC, DAPI, Carl Zeiss). Photographs were taken using digital camera (Olympus Camedia 750, Olympus, Tokyo, Japan). Program NIS-elements was used for evaluation of intensity of emission, all values were recalculated to control (100%). Ten random fields from each variant and replicate were evaluated.

For free zinc(II) ion staining, fluorescent probe N-(6-methoxy-8-quinolyl)-p-toluene sulphonamide (TSQ, Invitrogen) was used. Working solution (10 μM, phosphate buffer pH 7.6) was prepared by diluting of TSQ stock solution (10 mM, acetone). Cells were carefully rinsed by PBS buffer to remove all cultivation medium containing free zinc(II) ions, subsequently stained by working TSQ solution (30 min, 37°C, dark), three times washed by PBS buffer (pH 7.6) and observed under a fluorescence microscope (Axioskop 40, Carl Zeiss) equipped by FITC and DAPI filters (Carl Zeiss). Photographs were taken on digital camera (Olympus Camedia 750, Olympus). NIS-element program was used for evaluation of intensity of emission, all values were recalculated to control (=100%). Ten random fields from each variant and replicate were evaluated.

To select suitable concentration range of zinc(II) ions for treatment of the cell lines, we determined IC₅₀ values of zinc(II) for both cell lines using standard MTT cytotoxicity assay with simple linear regression from the descending part of the curve. We obtained IC₅₀ corresponding to concentration of 197.9 μM for non-tumour PNT1A and concentration of 369.1 μM for 22Rv1 tumour cells (Fig. 2A). Moreover, we found that PNT1A cells reached stationary phase of growth after 160 h while 22Rv1 cells after 240 h. Thus, we decided to use zinc(II) ion concentrations as follows: 0 (control), 25, 50, 75 and 100 μM for both cell lines for the monitoring of changes in gene expression for 240 h.

Further, we were interested to monitor growth of the cell lines in real time. It is difficult to monitor on-line growth of cell lines during experiment due to the destructive methods for its determination. xCELLigence system offers good possibility to monitor cell growth and proliferation in real time using impedance measurement (19), therefore, we used this system. Primarily, it was necessary to determine optimal cell counts for real time monitoring. We obtained optimal signal with 10,000 cells in each well. This signal corresponded to the cell count. In wells with lower cell count, lower relative impedance signal level was determined and, in some cases, higher relative standard deviation was obtained. Higher cell counts gave also well repeatable results with low relative standard deviation, however, higher count of cells was not optimal from the point of view of 240 h long experiment expecting increasing proliferation and therefore cell count. Therefore, we decided to use 10,000 cells per well to examine the effect of zinc(II) ions on prostatic cells either derived from normal prostate epithelium (PNT1A) or cells derived from primary prostate carcinoma (22Rv1). The IC₅₀ values of zinc(II) ions using the xCELLigence system were also determined to evaluate the selected concentration range. These IC₅₀ values were as follows: 150.8 μM zinc for PNT1A cells and 445.5 μM zinc for 22Rv1 cells. The changes between these values and values determined using MTT assay can be associated with the fact that both methods are based on measuring of very different physical parameters, which are associated with different physiological phenomena. Based on both measurements of IC₅₀ it may be concluded that zinc(II) ions are more toxic to non-tumour cell line at 2.9-fold lower concentration. Based on the obtained results 10,000 cells per well were treated with the above-mentioned concentrations of zinc(II) ions for 240 h. In the beginning of the treatment we observed negligible decrease in relative impedance, i.e. in growth, of PNT1A cells after 15-h long treatment (Fig. 2B) and no changes in cell proliferation of 22Rv1 cells (Fig. 2C). These changes were compared with cell lines treated with 0 μM of zinc(II) ions. Concentrations of 100 μM of zinc(II) ions induced 1.4-and 1.1-fold decrease of relative resistance in PNT1A and 22Rv1 cell lines, respectively, compared to non-treated samples. These results clearly show that the selected concentration range is non-toxic for both cell lines and we can observe the effects of physiological doses of zinc(II) ions on expression of the selected markers as Bcl-2, c-Fos, c-Jun, NF-κB, Ki-67 and p53.

Further, we focused on comparison of the base line expression and changes in transcription of Bcl-2, c-Fos, c-Jun, NF-κB, Ki-67 and p53 genes on the RNA level in prostate cell lines treated with zinc(II) ions. Baseline transcription level and zinc(II) ions effect on transcription levels of selected genes was performed by RT-PCR. Fig. 3 shows that 22Rv1 cells demonstrate different expression patterns in monitored genes compared to PNT1A cells. 22Rv1 cell line has 4.5-fold higher level of Bcl-2 anti-apoptotic gene expression (n=5). We found no significant differences (p>0.05) in c-Jun gene expression in either cell line. c-Fos gene that together with c-Jun forms important part of AP-1 transcription factor shows 2.5-fold down-regulation in 22Rv1 cells. Ki-67, a nuclear protein that is associated with cellular proliferation, is present in 22Rv1 cell line in 2-fold higher concentration compared to PNT1A. Moreover, NF-κB is present in half concentration in 22Rv1cells compared to PNT1A and p53, a key regulator of apoptosis, shows 3.3-fold decreased level compared with PNT1A cell line. After basic characterization of the expression of selected markers in both studied cell lines, we focused on zinc(II) ion treatment effect on the expression changes of these selected regulatory genes (Fig. 4).

We found that zinc(II) ions influence positively expression of Bcl-2 gene in both tested cell lines, however, more in PNT1A cells [≤3.2-fold change in case of 100 μM zinc(II) ions treatment]. In addition, we found no significant difference (p>0.05) in p53 expression levels after zinc treatment in 22Rv1 cell line (Fig. 4). On the other hand, zinc(II) ions treatment resulted in the increasing p53 expression from 3- up to 4.7-fold change in PNT1A. Ki-67 gene shows similar pattern in both cell lines after zinc(II) treatment and it is not surprising that 22Rv1 cell line, characterized by higher proliferation rate (Fig. 2A and B), demonstrated higher expression as a gene involved in the proliferation process. Zinc(II) ions had up-regulative effect on c-Jun gene in both cell lines. PNT1A demonstrated higher c-Jun expression in all zinc treatments compared to 22Rv1. In addition, we found no correlation between c-Jun and c-Fos gene expression after zinc treatment, but expression profile of c-Fos showed statistically significant positive correlation (data not shown) with expression of NF-κB gene after the treatment (compare trends in Fig. 4). Both genes are expressed in higher concentration in PNT1A cell line on the base expression level as well as after zinc treatment.

Subsequently, we focused on possible dependencies between Bcl-2 mRNA and the mRNA levels of other regulatory genes. After exposure to zinc(II) ions, we observed distinct trends between Bcl-2 and c-Fos and c-Jun and no significant correlations between Bcl-2 and Ki-67, NF-κB and p53 in either cell line (Fig. 5). Bcl-2-p53 showed strong positive correlation at r=0.61. In the case of c-Fos and c-Jun, we found strong positive correlations at r>0.85 in 22Rv1 tumour cell line and strong negative correlations at r<-0.50 in PNT1A non-tumour cell line. In terms of statistical significance, Bcl-2-c-Fos and - c-Jun showed correlations p<0.05 only in 22Rv1 cell line. In contrast, non-tumour cell line PNT1A showed an inverse trend i.e. decrease of Bcl-2 in relation to regulatory genes. In this cell line, negative significant correlation was detected at Bcl-2-c-Jun at p=0.10 with r=-0.79 (Fig. 5).

We characterized cell lines from the point of view of pro- and anti-apoptotic factor expressions, free zinc(II) ions were visualized using fluorescent probe N-(6-methoxy-8-quinolyl)-p-toluene sulphonamide, probe specific to these ions. Significant differences in zinc(II) ion localization in both non-tumour PNT1A cells (Fig. 6Aa-e) and tumour 22Rv1 (Fig. 6Ba-e) cells were found. For quantification of changes in free zinc(II) ion levels in cell lines, program NIS-elements for image analysis was used. Detected values (10 fields for each concentration and repetition) were recalculated to control cells (100%) (Fig. 6C). In both PNT1A and 22Rv1 cells, free zinc(II) ions levels were closely connected with zinc(II) ions treatment in concentration-dependent manner. In the case of PNT1A cell line, localization of zinc(II) ions around nuclei and irregularly in nuclei was evident in cells treated with the highest zinc(II) concentration (100 μM). Peripheral parts of cytoplasm demonstrate only weak emission, representing only low free zinc(II) levels in these localizations. In 22Rv1 cells, the intensity of emission of fluorescence product significantly increases with the increased supplementation of cultivation medium by zinc(II) ions (Fig. 6Ba-e). In the lowest Zn(II) supplementation, free zinc(II) ions were localized especially around the nuclei. At the highest Zn(II) supplementation, free zinc(II) ions were localized in nuclei and around the nuclei in the form of spots with high emission. The origin of these spots, which were visible only in the case of 22Rv1 cells in the highest Zn(II) ions supplementation, is probably the zincosomes, compartments of endoplasmic reticulum origin (20).

Compounds rich in -SH moieties including low molecular mass peptides and proteins as reduced glutathione and metallothionein (21-25) are responsible for binging metal ions in intracellular space. Therefore, monitoring of such compounds as well as detection of free zinc(II) ions can answer questions on metabolizing of metal ions in a cell. 5-(bromomethyl)fluorescein, the probe that provides formation of fluorescent product after reaction with -SH groups of thiols, was used for detection and cellular compartmentation of free thiols. In the case of both PNT1A (Fig. 6Af-j) and 22Rv1 cells (Fig. 6Bf-j), amount of free thiols continually decreases with the increasing zinc(II) ions supplementation, however, selection of cells with high content of free thiols was evident. This fact was evident in 22Rv1 cells treated with the highest Zn(II) concentration. In both cell lines, free thiols were localized around the nuclei and in nuclei in cells treated with lower Zn(II) concentrations. On the other hand, highest free thiols levels were detected in the nuclei in the case of tumour 22Rv1 cell line. This fact is evidence on the possible role of free thiols in transcriptional activity, which is regulated not only by free thiols, but also by zinc(II) ions whose concentration was high in nuclei in the same case.