Genes Associated With Prognosis After Surgery For Malignant Pleural Mesothelioma Promote Tumor Cell Survival In Vitro

The normal cell line WI38 and the tumor cell line A549 were purchased from the American Type Culture Collection (http://​www.​atcc.​org). Both cell lines were grown in 384-well plates (4titude, Surrey, United Kingdom) under RPMI1640 medium (Invitrogen, Carlsbad, California) supplemented with 10% calf serum and antibiotics. A549 cells were grown in wells coated with collagen I (BD Biosciences, San Jose, California).

A549 and WI38 cells were seeded at a density of 1,000 cells/well and 3,000 cells/well, respectively. One day post-seeding, cells were separately transfected with siRNAs (Applied Biosystems/Ambion Silencer ^® siRNA library, Austin, Texas) targeting positive control genes (KIF11, PLK1) or experimental genes (ARHGDIA, COBLL1, PKM2, TM4SF1) using Lipofectamine RNAiMax (Invitrogen) at 0.09 μl/well. A single siRNA molecule was used for each positive control gene: KIF11 (siRNA ID #105925), PLK1 (siRNA ID #213548). Positive control genes were chosen to monitor the performance of the assay as each gene is widely known to affect both mitosis and apoptosis. Three structurally distinct siRNA molecules were separately used for each experimental gene to confirm specificity of effect: ARHGDIA (siRNA IDs #119694, #119695, #119907), COBLL1 (siRNA IDs #136636, #136637, #136638), PKM2 (siRNA IDs #285, #286, #287), TM4SF1 (siRNA IDs #144307, #144308, #144309). All siRNAs were used at a final concentration of 30 nM. Negative controls consisted of scrambled, non-specific siRNAs and mock transfection (i.e., transfection mix only). Positive and negative controls were placed at multiple positions on the plate to control for positional effects (if any). Each cell line/siRNA molecule combination or cell line/mock transfection combination was conducted in triplicate, i.e., 3 wells per plate. All experiments were run in triplicate with a single experiment consisting of one plate to be used to assess knockdown efficiency (via quantitative RT-PCR) and a separate identical plate to be used for phenotypic and morphological assays described below.

Assessment of apoptosis and mitosis was conducted using a high-throughput approach [23]based on computer-assisted automated analysis of captured microscopic digital images [24, 25], conducted as part of a fee-for-service arrangement with Cenix Bioscience (http://​www.​cenix-bioscience.​com/​). General strategies to minimize false discoveries were used as previously described [26]. Essentially, siRNA-transfected and control adherent cells were fixed at 72-hours post-transfection using 4% paraformaldehyde in PBS, washed using PBS, and stored at 4°C until analyzed further. Detection of apoptotic and mitotic molecular markers was conducted using immunological assays after blocking in a buffer containing 0.1% Triton, 0.01% Saponin, and 4% BSA in PBS. Primary antibody solutions (1:200 rabbit anti-cleaved lamin A in blocking buffer for apoptosis; 1:900 mouse anti-phospho-histone H3 in blocking buffer; 1:100 rabbit anti-alpha-tubulin in blocking buffer to show cellular morphology) were applied overnight at 4°C. All primary antibodies were obtained from Cell Signaling Technology (Danvers, Massachusetts). After washing twice in PBS, a secondary antibody solution for was applied for 2 h at RT (goat anti-rabbit alexa488, goat anti-mouse alexa555, both antibodies from Invitrogen in a dilution of 1:1,000 + 1 μg/ml Hoechst 33342, in blocking buffer). Cells were washed three times in PBS and images were captured using an ImageXPress Micro automated microscope, with 10x objective, binning 2, 4 sites per well, Dapi/FITC/Cy3/Cy5 channels. QC analysis of digitally captured visual images containing fluorescent signals corresponding to apoptotic and mitotic molecular markers, as well as Hoechst staining of cellular DNA, was conducted using MetaMorph software (MDS Analytical Technologies, Downingtown, Pennsylvania). Quantitative auto-image analysis was conducted using eCognition software (Definiens, Parsippany, New Jersey) with rule sets optimized using data from positive control experiments.

Raw image data generated above was imported into Spotfire DXP software (Tibco, Palo Alto, California) to remove from consideration areas with high background, bad focus, and/or image haze. Images were quantified by first calculating a individual well average from 4 sites/well then calculating a triplicate average from the three well averages, per sample, per readout. Experimental data was then normalized (to 100%) using the average of negative control data per sample, per readout. For statistical analysis, the following indices were calculated: Apoptotic Index ({[number of cleaved lamin A positive cells]/[number of nuclei]}*100%), Mitotic Index ({[number of phospho-histone H3 positive cells]/[number of nuclei]}*100%), Condensed Chromatin Index ({[number of condensed chromatin positive cells]/[number of nuclei]}*100%), Aberrant Nuclei Index ({[number of aberrant nuclei]/[number of nuclei]}*100%), and the Cell Number Index (absolute number of nuclei). The Apoptotic and Mitotic Indices required co-localization of Hoechst stain and cleaved lamin A or phosphor-histone H3, respectively. The Condensed Chromatin and Aberrant Nuclei Indices were based on Hoechst stain intensity and nuclear shape parameters, respectively, that were defined based on analysis of positive control gene knockdown studies. Statistical analysis was performed using a two-sided Student's (parametric) t-test for pair-wise comparisons of average experimental and negative control index values. Data was initially collected and analyzed for only the Apoptotic and Mitotic Index. Therefore, to take into account multiple hypothesis testing, statistical significance at the P < 0.05 level was estimated by applying a corrective factor to experimental P values such that statistical significance was called when P < 0.00069 (i.e., 0.05/72 where 72 = 2 (cell lines) × 2 (index readouts) × 3 (siRNAs per gene) × 6 (genes). Uncorrected P values were used to evaluate subsequent indices (i.e., Condensed Chromatin, Aberrant Nuclei, Cell Number) since these data were analyzed only in tumor cells for the genes/siRNAs with statistically significant differences (i.e., P < 0.00069) previously identified in the Apoptotic Index.

Total RNA was extracted from 384-well plates using lysis buffer and the Invisorb kit (both from Invitek, Berlin, Germany). RT reactions were set up using Applied Biosystems (Foster City, California) HighCapacity cDNA reagents and random hexamer primers following the manufacturer's recommended protocol. PCR reactions were run on an Applied Biosystems 7900HT device using a SYBR Green fluorometric-based detection system (SensiMix 2X PCR master mix, Quantace, Freising, Germany). The total reaction volume was 11 μl and contained 500 nM of target specific primers[22]. Gene expression levels in experimental knockdown cell lines were expressed as a percentage of parental control.

All 6 genes (2 positive control and 4 experimental) were successfully targeted using 3 different siRNAs per gene as shown by reduced mRNA levels in normal and tumor knockdown cells relative to untransfected (parental) cells (Figure 1). Negative control cells transfected with non-specific (i.e., scrambled) siRNAs were not associated with changes in mRNA levels for any gene (data not shown). Gene expression levels for positive controls (KIF11, PLK1) and MPM prognostic genes (ARHGDIA, COBLL1, PKM2, TM4SF1) were reduced by ~50-80% in normal cells (Figure 1A). For reasons that were not immediately clear, a slightly more efficient knockdown was achieved in tumor cells (Figure 1B), as reflected by modestly reduced variability and lower overall mRNA levels.

Knockdown of ARHGDIA, COBLL1, and TM4SF1 resulted in increased levels of apoptosis in normal cells (ARHGDIA only) and tumor cells (ARHGDIA, COBLL1, TM4SF1) relative to negative controls. No changes were observed in apoptosis after knockdown of PKM2 or for mitosis after knockdown of any gene experimental gene. A representative image is shown in Figure 2 for ARHGDIA knockdown in tumor cells. To quantify these differences, we calculated Apoptotic and Mitotic Indices and found that apoptosis was statistically significantly elevated ~2- to 4-fold for silencing ARHGIA compared to negative control (siRNA1 P = 0.00067, siRNA2 P = 0.00098, siRNA3 P = 8.7 × 10^-10) in normal cells (Figure 3A). Silencing of other experimental genes were in some cases associated with a modestly elevated degree of apoptosis that, as expected, did not achieve statistical significance for any siRNA (Figure 3A). A similar statistically significant 2- to 4-fold increase in the degree of apoptosis was observed after knockdown of ARHGDIA (siRNA1 P = 1.5 × 10^-6, siRNA2 P = 1.2 × 10^-8, siRNA3 P = 5.5 × 10^-9), COBLL1 (siRNA1 P = 1.3 × 10^-5, siRNA2 P = 1.8 × 10^-5, siRNA3 P = 0.00063), and TM4SF1 (siRNA1 P = 7.3 × 10^-5, siRNA2 P = 5.3 × 10^-5, siRNA3 P = 3.2 × 10^-5), but not PKM2, in tumor cells (Figure 3B). Despite a clear mitotic arrest after knockdown of positive control genes, as expected no statistically significant changes were observed in the Mitotic Index for any experimental gene relative to negative controls (data not shown).

We examined nuclear morphology in experimental and control knockdown cell lines to look for relatively early indicators of apoptosis in order to complement studies described above in which apoptosis was measured using a relatively late indicator (e.g., cleaved lamin A). The numbers of cells with condensed nuclei, a hallmark of apoptosis, were increased in all positive control and knockdown cell lines that were previously associated with increased apoptosis as measured using cleaved lamin A, (e.g., ARHGDIA, COBLL1, TM4SF1) but not in the single knockdown cell line (PKM2) that was not. No statistically significant changes were observed in the numbers of aberrantly shaped nuclei under any circumstances by comparison of values calculated for the Aberrant Nuclei Index between experimental and controls (data not shown). A representative image is shown in Figure 4 for ARHGDIA knockdown in tumor cells. To quantify these differences, we calculated Condensed Chromatin and Aberrant Nuclei Indices. We found that ARHGDIA, COBLL1, and TM4SF1 knockdown cells were associated with a modest increase in the Condensed Chromatin Index (Figure 5A), although the results were statistically significant (P < 0.05) for siRNAs associated with a single experimental gene only (ARHGDIA; siRNA1 P = 0.004, siRNA2 P = 0.001, siRNA3 P = 0.001). As expected, no experimental gene/siRNA combination from the Aberrant Nuclei Index was statistically significantly (P < 0.05) different from the negative control.

To generate a Cell Number Index, we used absolute cell numbers (via enumeration of Hoechst-stained nuclei) as a surrogate to determine the effects, if any, of experimental gene knockdown on cellular proliferation. We found that cell numbers decreased (relative to negative controls) in ARHGDIA, COBLL1, and TM4SF1 knockdown cells (Figure 5B) in support of previous results showing an increase in apoptosis under the same conditions. The observed decrease in cell number was statistically significant (P < 0.05) for all siRNAs for each experimental gene (gene, individual siRNA P value): ARHGDIA, siRNA1 P = 0.012, siRNA2 P = 2.0 × 10^-12, siRNA3 P = 0.039; COBLL1, siRNA1 P = 0.008, siRNA2 P = 0.0006, siRNA3 P = 0.008; TM4SF1, siRNA1 P = 2.0 × 10^-19, siRNA2 P = 2.0 × 10^-5, siRNA3 P = 2.0 × 10^-11.