Replication Study: A coding-independent function of gene and pseudogene mRNAs regulates tumour biology
Abstract
As part of the Reproducibility Project: Cancer Biology we published a Registered Report (Khan et al., 2015), that described how we intended to replicate selected experiments from the paper "A coding-independent function of gene and pseudogene mRNAs regulates tumour biology" (Poliseno et al., 2010). Here we report the results. We found PTEN depletion in the prostate cancer cell line DU145 did not detectably impact expression of the corresponding pseudogene PTENP1. Similarly, depletion of PTENP1 did not impact PTEN mRNA levels. The original study reported PTEN or PTENP1 depletion statistically reduced the corresponding pseudogene or gene (Figure 2G; Poliseno et al., 2010). PTEN and/or PTENP1 depletion in DU145 cells decreased PTEN protein expression, which was similar to the original study (Figure 2H; Poliseno et al., 2010). Further, depletion of PTEN and/or PTENP1 increased DU145 proliferation compared to non-targeting siRNA, which was in the same direction as the original study (Figure 2F; Poliseno et al., 2010), but not statistically significant. We found PTEN 3'UTR overexpression in DU145 cells did not impact PTENP1 expression, while the original study reported PTEN 3'UTR increased PTENP1 levels (Figure 4A; Poliseno et al., 2010). Overexpression of PTEN 3'UTR also statistically decreased DU145 proliferation compared to controls, which was similar to the findings reported in the original study (Figure 4A; Poliseno et al., 2010). Differences between the original study and this replication attempt, such as level of knockdown efficiency and cellular confluence, are factors that might have influenced the results. Finally, where possible, we report meta-analyses for each result.
Introduction
The Reproducibility Project: Cancer Biology (RP:CB) is a collaboration between the Center for Open Science and Science Exchange that seeks to address concerns about reproducibility in scientific research by conducting replications of selected experiments from a number of high-profile papers in the field of cancer biology (Errington et al., 2014). For each of these papers a Registered Report detailing the proposed experimental designs and protocols for the replications was peer reviewed and published prior to data collection. The present paper is a Replication Study that reports the results of the replication experiments detailed in the Registered Report (Khan et al., 2015) for a paper by Poliseno et al., and uses a number of approaches to compare the outcomes of the original experiments and the replications.
In 2010, Poliseno et al. reported PTENP1, the pseudogene of the tumor suppressor PTEN, acted as a repressor (molecular sponge) of PTEN-targeting microRNAs and, in turn, regulated cellular PTEN expression and function. Pseudogenes are non-coding genomic DNA sequences that share high sequence similarity with their cognate protein-coding genes (Haddadi et al., 2018). The 3’UTR sequences of PTEN and PTENP1 share common putative microRNA binding site and overexpression of miR-19b and miR-20a in the prostate cancer cell line DU145 resulted in decreased PTEN and PTENP1 mRNA levels (Poliseno et al., 2010). The regulatory role of PTENP1 was demonstrated in knockdown experiments where reduction of PTENP1 resulted in decreased PTEN mRNA and PTEN protein levels and increased proliferation of DU145 cells (Poliseno et al., 2010). Similar biological activity of the 3’UTR of PTEN was also reported where overexpression of PTEN 3’UTR derepressed PTENP1 expression and inhibited DU145 proliferation (Poliseno et al., 2010).
The Registered Report for the paper by Poliseno et al. described the experiments to be replicated (Figures 1D, 2F–H and 4A), and summarized the current evidence for these findings (Khan et al., 2015). Since that publication additional studies have reported the biological activity of PTENP1 in various tumors. In esophageal squamous cell carcinoma (Gong et al., 2017) and oral squamous cell carcinoma (Gao et al., 2017), overexpression of PTENP1 decreased proliferation and colony formation in vitro and inhibited tumor growth in xenograft models. In head and neck squamous cell carcinoma (Liu et al., 2017), hepatocellular carcinoma (Chen et al., 2015; Qian et al., 2017), and bladder cancer (Zheng et al., 2018), PTENP1 overexpression increased PTEN mRNA expression and decreased proliferation, colony formation, invasion, and migration in vitro and inhibited growth in xenograft models. In gastric cancer, PTENP1 overexpression led to increased PTEN mRNA and PTEN protein levels, decreased cell proliferation and induced apoptosis, and inhibited migration and invasive ability of gastric cancer cells (Zhang et al., 2017). In clear-cell renal cell carcinoma overexpression of PTENP1 in cells reduced cell proliferation, migration, and invasion in vitro and tumor growth and metastasis in xenograft models (Yu et al., 2014). Overexpression of PTENP1 was reported to decrease proliferation, colony formation, and migration in the breast cancer cell line MCF7 (Chen et al., 2017; Gao et al., 2019; Shi et al., 2018), while Yndestad et al., 2018 reported decreased PTEN mRNA expression and accelerated MCF7 tumor growth. However, in ER-negative breast cancer cells, PTENP1 upregulation increased PTEN mRNA expression and inhibited tumor progression (Gao et al., 2019; Li et al., 2017; Shi et al., 2018; Yndestad et al., 2018). Additional competing endogenous RNAs (ceRNAs) that modulate PTEN through microRNA competition were identified using a computational model expanding upon the work reported in Poliseno et al. (2010) to propose a unifying hypothesis of regulatory networks composed of ceRNAs (Tay et al., 2011). In addition to PTEN/PTENP1, the pseudogene of oncogenic BRAF, BRAFP1 has been reported to regulate BRAF expression and subsequently affect MAPK signaling and proliferation, and drive tumorigenesis in vivo (Karreth et al., 2015). Recently, it has also been reported an extensive gene/pseudogene network that is comprised of multiple microRNAs and multiple pseudogenes derived from a single parental gene (Chan et al., 2018) with the potential of thousands of novel pseudogene-gene associations beginning to be explored through bioinformatic tools that have been developed (Johnson et al., 2019).
The outcome measures reported in this Replication Study will be aggregated with those from the other Replication Studies to create a dataset that will be examined to provide evidence about reproducibility of cancer biology research, and to identify factors that influence reproducibility more generally.
Results and discussion
Cell growth assay following siRNA transfection
We independently replicated an experiment to examine the consequences of PTEN and/or PTENP1 downregulation on DU145 cell proliferation. This experiment was described in Protocol 2 in the Registered Report (Khan et al., 2015) and is similar to Figure 2H of Poliseno et al. (2010) that reported PTENP1 downregulation accelerated cell proliferation with the strongest effect observed when PTEN and PTENP1 were both silenced. We utilized the same designed custom siRNA pools as the original study to specifically target either PTEN or PTENP1, as well as a commercially available PTEN siRNA pool that binds common sequences in PTEN and PTENP1. Proliferative activity was determined using the crystal violet assay each day after transfection for a total of 5 days with results presented relative to the values at the start of the time course for each condition (i.e., for each condition the average relative cell number at the start of the time course was set to 1) (Figure 1, Figure 1—figure supplement 1A). We found that compared to cells transfected with non-targeting siRNA (average Day 5 relative cell number (Avg Day 5#) = 10.2), there was increased cell proliferation when cells were transfected with either the PTENP1 specific siRNA (Avg Day 5# = 24.1) or the siRNA pool targeting PTEN and PTENP1 (Avg Day 5# = 25.0). Additionally, there was a minor increase in cell proliferation when cells were transfected with the PTEN specific siRNA (Avg Day 5# = 12.2). Interestingly, untransfected cells, a condition not reported in the original study, displayed a cell proliferation profile (Avg Day 5# = 21.3) more similar to cells transfected with either the PTENP1 specific siRNA or the siRNA pool targeting PTEN and PTENP1 than the non-targeting siRNA. This could be a result of transfection-mediated cytotoxicity and/or off-target siRNA effects that can generate cellular stress leading to decreased cell growth (Antczak et al., 2014; Fedorov, 2006; Wei et al., 2012) and is a factor to consider when interpreting these results, especially when considering the low level of increased cell growth in cells depleted of PTEN despite efficient knockdown (Figure 2A). The original study reported increased cell proliferation, compared to non-targeting siRNA, when cells were transfected with either the PTEN specific siRNA (Avg Day 5# = 4.15) or the PTENP1 specific siRNA (Avg Day 5# = 2.61), with the strongest effect being observed when cells were transfected with the siRNA pool targeting PTEN and PTENP1 (Avg Day 5# = 5.41) (Poliseno et al., 2010). In the original study the control condition (cells transfected with non-targeting siRNA) had a minimal impact on cell proliferation during the course of the experiment (Avg Day 5# = 1.60) (Poliseno et al., 2010). Importantly, the results of both studies should take into consideration that the doubling time for DU145 cells has been reported as ~29 hr (Lin et al., 1998), which would correspond to an Avg Day 5# of ~18, assuming cells maintained exponential phase growth. Additionally, the difference in achieved knockdown between the original study and this replication attempt is a possible reason for the differences in outcomes between the two studies. The experiment that assessed the level of knockdown in this replication is described in the section below (Figure 2) and compared to the results reported in the original study. Various levels of downregulation can give various phenotype effects, thus a higher level of knockdown might be required to observe an effect with this experimental design. Although, observing different outcomes are informative to establish the range of conditions under which a given phenotype can be observed (Bailoo et al., 2014).
The analysis plan specified in the Registered Report (Khan et al., 2015) proposed to compare the Avg Day 5# for the cells transfected with the various siRNAs. To test if downregulation of PTEN and/or PTENP1, was effective in increasing DU145 cell proliferation we performed an analysis of variance (ANOVA). The ANOVA result was statistically significant for the PTENP1 main effect (F(1,16) = 13.8, p=0.0019). Thus, the null hypothesis that there is no difference in cell proliferation when PTENP1 is downregulated, whether there was or was not downregulation of PTEN, can be rejected. The main effect for PTEN downregulation (F(1,16) = 0.15, p=0.703) and the interaction (F(1,16) = 0.02, p=0.878) were not statistically significant. We planned to conduct five comparisons using the Bonferroni correction to adjust for multiple comparisons, making the a priori adjusted significance threshold 0.01. According to this criterion, none of the planned comparisons were statistically significant (see Figure 1 figure legend). The same analysis was conducted using area under the curve (AUC) during the timecourse for each biological repeat, which gave similar results (Figure 1—figure supplement 1B). To summarize, for this experiment we found results that were generally in the same direction as the original study (i.e., increased cell proliferation when PTEN and/or PTENP1 were downregulated compared to non-targeting siRNA) and not statistically significant where predicted.
Quantitative PCR following transfection with siRNA against PTEN and/or PTENP1
To determine the knockdown efficiency of PTEN and PTENP1 in DU145 cells we performed qRT-PCR following transfection with the same siRNAs targeting PTEN and/or PTENP1 described above. This experiment also tested whether PTENP1 knockdown resulted in decreased PTEN mRNA, and vice versa. This is similar to what was reported in Figure 2G of Poliseno et al. (2010) and described in Protocol 3 in the Registered Report (Khan et al., 2015). We found that compared to cells transfected with non-targeting siRNA (mean relative expression = 1.00), cells transfected with PTEN specific siRNA or the siRNA pool targeting PTEN and PTENP1 resulted in decreased PTEN expression with relative mean values of 0.298 and 0.317, respectively, which were both statistically significant (non-targeting vs. si-PTEN: t(16) = 4.66, uncorrected p=0.00026, corrected p=0.0016; non-targeting vs. si-PTEN/PTENP1: t(16) = 4.54, uncorrected p=0.00034, corrected p=0.0020) (Figure 2A). Cells transfected with PTENP1 specific siRNA, however, resulted in a slight decrease in PTEN expression (mean relative expression = 0.883), which was not statistically significant (t(16) = 0.78, uncorrected p=0.448, corrected p>0.99). Similarly, cells transfected with PTENP1 specific siRNA or the siRNA pool targeting PTEN and PTENP1, resulted in decreased relative PTENP1 expression with relative mean values of 0.287 and 0.453, respectively; while PTENP1 expression was slightly decreased following transfection with PTEN specific siRNA (mean relative expression = 0.797) (Figure 2B). According to the criterion predefined in the Registered Report, cells transfected with PTENP1 specific siRNA were statistically significant (non-targeting vs. si-PTENP1: t(16) = 3.89, uncorrected p=0.0013, corrected p=0.0079), while the other two comparisons were not (non-targeting vs. si-PTEN/PTENP1: t(16) = 2.98, uncorrected p=0.0089, corrected p=0.053; non-targeting vs. si-PTEN: t(16) = 1.10, uncorrected p=0.286, corrected p>0.99). The original study reported statistically significant decreases in PTEN and PTENP1 expression for all of the comparisons between cells transfected with non-targeting siRNA and either si-PTEN, si-PTENP1, or the siRNA pool targeting PTEN and PTENP1. In the original study PTEN expression was decreased with relative mean values of ~0.12, ~0.38, and ~0.19 and PTENP1 expression was decreased with relative mean values of ~0.54, ~0.27, and ~0.48 for si-PTEN, si-PTENP1, and si-PTEN/PTENP1, respectively (Poliseno et al., 2010). Further, these replication and original results used ß-ACTIN as the internal standard to normalize PTEN and PTENP1 expression. We also normalized the PTEN and PTENP1 levels from this experiment to 36B4, as suggested during peer review of the Registered Report (Davis, 2015), and found similar results (Figure 2—figure supplement 1). To summarize, for this experiment we found results that were in the same direction as the original study and statistically significant for confirming knockdown of PTEN or PTENP1 with target specific siRNA; however results were not statistically significant for other comparisons (i.e., PTEN mRNA levels following PTENP1 knockdown, and vice versa).
There are a number of factors that could affect these experiments and should be considered when interpreting these data. Although qRT-PCR is a common laboratory technique there are a number of steps and reagents that can vary in experimental protocols and data analyses among different laboratories (Kuang et al., 2018; Miranda and Steward, 2017; Taylor et al., 2019). While this replication attempted to mirror the approach taken in the original study it was limited to what was obtainable from the original paper and through communication with the original authors. Similarly, the raw data (e.g., levels of ß-ACTIN in the PCR reaction) from the original study were unknown and thus can not be directly compared to this replication attempt. Additionally, cell to cell contact has been reported to active microRNA biogenesis globally (Hwang et al., 2009). Thus, the level of cellular confluence, which was not able to be compared between the original study and this replication attempt, is another factor that needs to be considered. Finally, the higher variability observed in this study is one of the factors that could influence if statistical significance is reached, particularly since the sample size of this replication attempt was determined a priori to detect the effect based on the originally reported data.
Western blot of cells transfected with siRNA
We also examined the knockdown efficiency and impact of PTENP1 knockdown on PTEN protein levels using the same siRNAs targeting PTEN and/or PTENP1 described above and the same PTEN antibody as the original study. This is similar to what was reported in Figure 2H of Poliseno et al. (2010) and described in Protocol 4 in the Registered Report (Khan et al., 2015). We found that compared to cells transfected with non-targeting siRNA (mean relative expression = 1.00), cells transfected with PTEN specific siRNA, PTENP1 specific siRNA, or the siRNA pool targeting PTEN and PTENP1 resulted in decreased PTEN expression with relative mean values of 0.41, 0.65, and 0.17, respectively (Figure 3). The original study reported that compared to non-targeting siRNA (relative expression = 1.00) the relative PTEN expression was 0.50 for cells transfected with PTEN specific siRNA, 0.60 for cells transfected with PTENP1 specific siRNA, and 0.10 for cells transfected with the siRNA pool targeting PTEN and PTENP1.
To compare the relative PTEN expression among the various conditions, we planned to conduct five comparisons using the Bonferroni correction to adjust for multiple comparisons, making the a priori adjusted significance threshold 0.01. Using the Wilcoxon-Mann-Whitney test we found statistically significant differences between non-targeting siRNA and si-PTEN (U = 25, uncorrected p=0.0079, corrected p=0.040), non-targeting siRNA and si-PTEN/PTENP1 (U = 25, uncorrected p=0.0079, corrected p=0.040), and si-PTENP1 and si-PTEN/PTENP1 (U = 0, uncorrected p=0.0079, corrected p=0.040). The comparisons between non-targeting siRNA and si-PTENP1 (U = 21, uncorrected p=0.095, corrected p=0.476) and si-PTEN and si-PTEN/PTENP1 (U = 6, uncorrected p=0.222, corrected p>0.99) were not statistically significant. To summarize, for this experiment we found results that were in the same direction as the original study with statistically significant decreases in relative PTEN expression from cells transfected with si-PTEN or si-PTEN/PTENP1 compared to non-targeting siRNA or si-PTENP1, while the differences in relative PTEN expression between non-targeting siRNA and si-PTENP1, and si-PTEN and si-PTEN/PTENP1, were not statistically significant.
Quantitative PCR following PTEN 3′ UTR transfection
DU145 cells were transfected with a plasmid designed to express the PTEN 3’UTR to test if the PTEN 3’UTR exerted a biological role on PTENP1. This was described in Protocol 5 in the Registered Report (Khan et al., 2015) and is similar to Figure 4A of Poliseno et al. (2010) that reported PTEN 3’UTR derepressed PTENP1 abundance. We found PTENP1 abundance was similar and not statistically significant (two sample t test: t(4) = 0.46, p=0.671) between cells transfected with a vector control plasmid (mean relative expression = 1.00) and cells transfected with PTEN 3’UTR (mean relative expression = 0.95) (Figure 4). The original study reported a statistically significant increase in PTENP1 expression when cells were transfected with a plasmid that expressed the PTEN 3’UTR (mean relative expression = ~3.88) compared to vector control (mean relative expression = 1.00) (Poliseno et al., 2010). Similar to the above experiments, these results used ß-ACTIN as the internal standard to normalize PTENP1 expression; however when we used 36B4 to normalize PTENP1 levels we found similar results (Figure 4—figure supplement 1). To summarize, for this experiment we found results that were not in the same direction as the original study and not statistically significant where predicted. The level of PTEN 3’UTR expression was not determined for this experiment and thus is a possible reason for differences in outcomes between the original study and this replication attempt. Additionally, as noted above, potential differences between the original study and this replication attempt are factors that need to be considered when interpreting these results. These include, but are not limited to, variations in expression levels of the internal standards used to normalize PTENP1 expression, differences in observed biological variability between the original study and this replication attempt, and cellular confluence, which has been reported to modify the levels of microRNA expression and thus their target constructs (Hwang et al., 2009).
Cell growth assay following PTEN 3′ UTR transfection
The impact of PTEN 3’UTR overexpression on DU145 cell proliferation was also examined. This is similar to what was reported in Figure 4A of Poliseno et al. (2010) and described in Protocol 6 in the Registered Report (Khan et al., 2015). Using the crystal violet assay, proliferative activity was determined each day after transfection for a total of 5 days with results presented relative to the values at the start of the timecourse for each condition (same approach as described above) (Figure 5, Figure 5—figure supplement 1A). We found that compared to cells transfected with a vector control plasmid (Avg Day 5# = 3.79), there was growth inhibition observed when cells were transfected with PTEN 3’UTR (Avg Day 5# = 2.72), which was statistically significant (two sample t test: t(4) = 9.25, p=0.00076). The same analysis was conducted using AUC during the 5 day timecourse for each biological repeat, which gave similar results (Figure 5—figure supplement 1B). In addition, untransfected cells displayed a cell proliferation profile similar to the vector control (Figure 5, Figure 5—figure supplement 1). In the original study, overexpression of PTEN 3’UTR inhibited cell proliferation (Avg Day 5# = ~5.24) compared to vector control (Avg Day 5# = ~7.17) (Poliseno et al., 2010). Interestingly, the growth profiles of the control conditions differed between this experiment and the experiment described above where DU145 cells were transfected with different siRNAs. Importantly, in this replication attempt this experiment and the cell growth assay presented in Figure 1 were conducted by two independent labs, therefore operator and/or environmental differences could be contributing factors. This could also be the result of cells being in the lag phase of cell growth at the start of the experiment instead of exponential phase growth, which could be caused by the seeding density and/or the in vitro age of the cultures (Selli et al., 2016). The original study also reported different cell growth profiles between the control conditions in the knockdown and overexpression experiments. Furthermore, the growth inhibition observed in the original study in cells that overexpressed PTEN 3’UTR was correlated with an increase in PTENP1 abundance, which, as described above (Figure 4), was not observed in this replication attempt. To summarize, for this experiment we found results that were in the same direction as the original study and statistically significant where predicted.
Meta-analyses of original and replication effects
We performed a meta-analysis using a random-effects model, where possible, to combine each of the effects described above as pre-specified in the confirmatory analysis plan (Khan et al., 2015). To provide a standardized measure of the effect, a common effect size was calculated for each effect from the original and replication studies. Cohen’s d is the standardized difference between two means using the pooled sample standard deviation, while the effect size Glass’ delta is standardized difference between two means using the standard deviation of only the control group. Glass’ delta was used when the variance between the two conditions were not equal, which occurred in the original study for some of the experiments. The estimate of the effect size of one study, as well as the associated uncertainty (i.e., confidence interval), compared to the effect size of the other study provides one approach to compare the original and replication results (Errington et al., 2014; Valentine et al., 2011). Importantly, the width of the confidence interval (CI) for each study is a reflection of not only the confidence level (e.g., 95%), but also variability of the sample (e.g., SD) and sample size.
There were five comparisons of the Day five relative cell number data from DU145 cells that were transfected with siLUC, si-PTEN, si-PTENP1, or si-PTEN/PTENP1, which were reported in Figure 1 of this study and Figure 2F of Poliseno et al. (2010). In all comparisons the results were consistent when considering the direction of the effect; however the effect size point estimate of each study was not within the CI of the other study (Figure 6A). Further, the meta-analyses were not statistically significant for any of the comparisons (see Figure 6A figure legend). For three of the comparisons, the large CI of the meta-analyses along with statistically significant Cochran’s Q tests (siLUC and si-PTEN, p=0.0253; siLUC and si-PTEN/PTENP1, p=0.0349; si-PTEN/PTENP1 and si-PTENP1, p=0.0235) suggest heterogeneity between the original and replication studies.
PTEN and PTENP1 mRNA expression were also examined in DU145 cells transfected with siLUC, si-PTEN, si-PTENP1, or si-PTEN/PTENP1, reported in Figure 2 of this study and Figure 2G of Poliseno et al. (2010), in which a total of six comparisons were made. With the PTEN mRNA expression data, two comparisons (siLUC and si-PTEN; siLUC and si-PTEN/PTENP1) had effects in the same direction for both the original study and this replication attempt, with the CI of each study encompassing the effect size point estimate of the other study (Figure 6B). The third comparison (siLUC and si-PTENP1) had effects in the same direction for both studies, but the point estimate of the original study was not within the CI of the replication. Furthermore, the meta-analyses for the first two comparisons were statistically significant (siLUC and si-PTEN, p=0.0013; siLUC and si-PTEN/PTENP1, p=0.0019), while the meta-analysis of the third comparison was not statistically significant (siLUC and si-PTENP1, p=0.244). These meta-analyses suggest transfection with si-PTEN or si-PTEN/PTENP1 decreased PTEN expression, while with the si-PTENP1 transfection the null hypothesis that there is no difference in PTEN mRNA expression can not be rejected. With the PTENP1 mRNA expression data, each of the three comparisons were consistent with respect to the direction of the effect; however, for each comparison the point estimate of the replication fell within the CI of the original study, but not vice versa. For the meta-analyses, two comparisons were not found to be statistically significant (siLUC and si-PTEN, p=0.225; siLUC and si-PTENP1, p=0.060), while one was (siLUC and si-PTEN/PTENP1, p=0.049). These meta-analyses suggest transfection with si-PTEN/PTENP1 decreases PTENP1 expression, while with the two null hypotheses that there are no differences in PTENP1 expression after transfection with si-PTEN or si-PTENP1 can not be rejected.
The original study results of the Western blot data examining PTEN protein levels after transfection with siRNAs targeting PTEN and/or PTENP1 were reported for a single representative image (Figure 2H; Poliseno et al., 2010). These values were compared to the values reported in this replication attempt and for each of the conditions tested the values reported in the original study were within the CI of this replication attempt (Figure 3A).
The effect sizes calculated from the PTENP1 mRNA expression data between DU145 cells transfected with pCMV or pCMV-PTEN-3’UTR, which were reported in Figure 4 of this study and Figure 4A of Poliseno et al. (2010), were in opposite directions between the two studies and the effect size point estimate of each study was not within the CI of the other study (Figure 6C). Furthermore, the meta-analysis was not statistically significant (p=0.485) with a large CI and a statistically significant Cochran’s Q test (p=0.0425) that suggests heterogeneity between the original and replication studies.
For the Day five relative cell number data from DU145 cells transfected with pCMV or pCMV-PTEN-3’UTR, reported in Figure 5 of this study and Figure 4A of Poliseno et al. (2010), the calculated effect sizes were consistent when considering direction (Figure 6D). The replication effect size point estimate fell within the CI of the original study, but not vice versa. A meta-analysis of these effects were found to be statistically significant (p=0.0093), suggesting transfection of DU145 cells with a plasmid designed to express the PTEN 3’UTR inhibited growth compared to a vector control plasmid.
This direct replication provides an opportunity to understand the present evidence of these effects. Any known differences, including reagents and protocol differences, were identified prior to conducting the experimental work and described in the Registered Report (Khan et al., 2015). However, this is limited to what was obtainable from the original paper and through communication with the original authors, which means there might be particular features of the original experimental protocol that could be critical, but unidentified. So while some aspects, such as cell lines, number of cells plated, and the specific siRNA sequences were maintained, others were unknown or not easily controlled for. These include variables such as cell line genetic drift (Hughes et al., 2007; Kleensang et al., 2016), and impacts of atmospheric oxygen on cell viability and growth (Boregowda et al., 2012). Whether these or other factors influence the outcomes of this study is open to hypothesizing and further investigation, which is facilitated by direct replications and transparent reporting.
Materials and methods
As described in the Registered Report (Khan et al., 2015), we attempted a replication of the experiments reported in Figures 2F–H and 4A of Poliseno et al. (2010). A detailed description of all protocols can be found in the Registered Report (Khan et al., 2015) and are described below with additional information not listed in the Registered Report, but needed during experimentation.
Cell culture
Request a detailed protocolDU145 cells (ATCC, cat# HTB-81, RRID:CVCL_0105) were grown in RPMI 1640 supplemented with 10% Fetal Bovine Serum (FBS), 100 U/ml penicillin, 100 µg/ml streptomycin, and 2 mM L-glutamine. Cells were maintained at 37°C in a humidified atmosphere at 6% CO2. Quality control data for the experiments presented in Figures 1–3 are available at https://osf.io/zxuya/, while data for the experiments presented in Figures 4, 5 are available at https://osf.io/b4rt2/. This includes results confirming the cell lines were free of mycoplasma contamination as well as STR DNA profiling of the cell lines, which were confirmed to be the indicated cell lines when queried against STR profile databases. Test for mycoplasma was performed by DDC Medical (Fairfield, Ohio) or using the MycoProbe Mycoplasma Detection Assay Kit (R and D Systems, cat# CUL0001B, lot# P104920). STR profile was performed by DDC Medical or Genetica Cell Line Testing (Burlington, North Carolina).
siRNA transfection and crystal violet proliferation assay
Request a detailed protocolDU145 cells were seeded at 1.5 × 105 cells per well in a 12 well plate and grown overnight. The next day cells were transfected using Dharmafect according to manufacturer’s instructions with 25 nM siGlo RISC-free siRNA (Dharmacon, cat# D-001600–01), 100 nM siGENOME non-targeting siRNA #2 (siLuc; Dharmacon, cat# D-001210–02), 100 nM PTEN-specific SMARTpool siPTEN; Dharmacon; sequences reported in Supplementary Figure 6 of Poliseno et al. (2010), 100 nM PTENP1-specific SMARTpool siPTENP1; Dharmacon; sequences reported in Supplementary Figure 6 of Poliseno et al. (2010), 100 nM ON-TARGETplus siPTEN SMARTpool (siPTEN/PTENP1; Dharmacon, cat# L-003023–00), or left untransfected. After 24 hr, microscopy was performed on cells transfected with siGlo and untransfected cells to ascertain transfection efficiency, which was observed to be >90%. Cells transfected with siLuc, siPTEN, siPTENP1, siPTEN/PTENP1, or untransfected were plated at 8,000 cells per well (in triplicate) in 12 well plates (enough for 6 days of measurements) with 2 ml of growth medium. Starting the day after plating (designated day 0), every 24 hr the crystal violet assay was performed as described in the Registered Report. Additionally, two additional cohorts (wells in triplicate) were included: unseeded (i.e., no cells) wells were treated with the Crystal Violet reagent (Blank treated) and unseeded wells left entirely untreated (Blank untreated). The average value from Blank treated was subtracted from each data point to correct for background staining of crystal violet to the plastic dish. For each independent biological repeat, average absorbance (OD590) for each condition was normalized by dividing the average absorbance of each day to the average absorbance for day 0 to calculate relative cell number. Area under the curve (AUC) was calculated for each condition of each biological repeat. Data files are available at https://osf.io/xyefm/.
siRNA transfection and quantitative PCR
Request a detailed protocolDU145 cells were seeded and transfected as described above in ‘siRNA transfection and crystal violet proliferation assay’. 24 hr after transfection, total RNA was extracted with TRI Reagent (Sigma-Aldrich, cat# T9424) added directly to each tissue culture dish with 1-bromo-3-chloropropane (Sigma-Aldrich, cat# B9673) added to the homogenous lysate according to manufacturer’s instructions. The RNA pellet was dried and stored at −80°C until shipped on dry-ice for quantitative PCR. RNA concentration and purity was determined (quality control data available at https://osf.io/yh8z9/). Total RNA was reverse transcribed into cDNA using a First-Strand cDNA Synthesis Kit (Sigma-Aldrich, cat# GE27-9261-01) according to manufacturer’s instructions. Reactions consisted of cDNA (2 µl of 10 ng/µl), qPCR Mastermix, ultrapure water, and primers (forward and reverse primers are listed in the Registered Report Protocol 3; Khan et al., 2015). qRT-PCR reactions were performed in technical triplicate with QuantiTect Sybr Green PCR Kit (Qiagen, cat# 204141) according to manufacturer’s instructions. PCR cycling conditions were: one cycle: 95°C for 30 s – 40 cycles: [95°C for 10 s, 60°C for 30 s] – one cycle: 95°C for 30 s, 65–95°C (ramp 0.5°C every 5 s) using a BioRad CFX96 qPCR system (Hercules, California) and CFX Manager software (RRID:SCR_017251), version 3.1.1517.0823. Negative controls containing no cDNA template were included. It was discovered the melting curves for PTEN and PTENP1 were inconsistent and required repeating measuring. Relative expression levels were determined using the ∆∆Ct method. Data files are available at https://osf.io/6zbdt/.
siRNA transfection and western blot
Request a detailed protocolDU145 cells were seeded at 3.75 × 105 cells per well in a six well plate and transfected with siRNAs as described above in ‘siRNA transfection and crystal violet proliferation assay’. 48 hr after transfection, cells were prepared in lysis buffer (50 mM Tris, pH 8.0, 150 mM NaCl, 1% NP-40, 1 mM EDTA, 1 mM MgCl2, 1 mM ß-glycerophosphate, 1 mM NaF, and 1 mM Na3VO4), supplemented with protease inhibitors (Sigma-Aldrich, cat# P8340) at manufacturer recommended concentrations. Lysed cells were incubated on ice for 30 min, gently sonicated for 3 to 4 bursts for 5 to 10 s, and centrifuged at 10,000xg for 10 min at 4°C before protein concentration of supernatant was quantified using a Bradford assay following manufacturer’s instructions. Lysate samples (2.5 µg was used after optimization studies) were separated by 4–12% Tris Glycine SDS-PAGE gel electrophoresis with 5 µl of an ECL marker (Sigma-Aldrich, cat# GERPN810) and then transferred to a nitrocellulose membrane as described in the Registered Report (Protocol 4; Khan et al., 2015), except membranes were not washed with methanol prior to transfer. Transfer was confirmed by Ponceau S staining and membranes were blocked with 5% non-fat dry milk in 1X TBS with 0.1% Tween-20 (TBST) overnight at 4°C. Membranes were probed with the following primary antibodies diluted in 5% non-fat dry milk in TBST for 2 hr at room temperature: rabbit anti-PTEN [clone 138G5] (Cell Signaling Technology, cat# 9559, RRID:AB_390810), 1:1000 dilution; mouse anti-HSP90 [clone 68] (BD Biosciences, cat# 610419, RRID:AB_397798), 1:1000 dilution. Membranes were washed with TBST and incubated with secondary antibody diluted in 5% non-fat dry milk in TBST: HRP-conjugated goat anti-rabbit (Cell Signaling Technology, cat# 7074, RRID:AB_2099233), 1:20,000 dilution; HRP-conjugated horse anti-mouse (Cell Signaling Technology, cat# 7076, RRID:AB_330924), 1:20,000 dilution. Membranes were washed with TBST and incubated with ECL reagent to visualize signals. Scanned Western blots were quantified using ImageJ software (RRID:SCR_003070), version 1.50a (Schneider et al., 2012). Additional methods and data, including full Western blot images, are available at https://osf.io/re87y/.
PTEN 3’UTR plasmid generation
Request a detailed protocolTo generate pCMV-PTEN-3’UTR (deposited in Addgene, plasmid# 97204; RRID:Addgene_97204), PTEN 3’UTR was amplified from HeLa genomic DNA (New England BioLabs, cat# N4006) by PCR using KAPA Bio’s HiFi Hotstart ReadyMix (Kapa Biosystems, cat# KM2605) and the following primers (BamH1 forward primer: 5’-GGATCCTAGAGGAGCCGTCAAATCCA-3’; XhoI reverse primer: 5’-CTCGAGTGGACATCTGATTGGGATGA-3’). PCR cycling conditions were: one cycle: 98°C for 30 s – 35 cycles: 98°C for 15 s, 64°C for 30 s, 72°C for 3 min 30 s – one cycle: 72°C for 2 min. Following multiple unsuccessful attempts to clone the PCR product (~3.3 kb) into the pCMV vector (Agilent Technologies, cat# 240071) (direct, TOPO TA, Gibson assembly), we were successful by cloning partial fragments. The full-length PTEN 3’UTR PCR product was able to be broken into three fragments with the following primers and cycling conditions. PCR primers and parameters for CMV-PTEN-3’UTR minus middle SpeI-BstXI fragment: [CMV-PTEN-3’UTR minus SpeI/BstXI forward primer: 5’-GAAATTTGGTGTCTTCAAATTATACCTTCAC-3’; CMV-PTEN-3’UTR minus SpeI/BstXI reverse primer: 5’-TTGAAAACTAGTAAAATAAGTGTAAGTTGTTGACTG-3’]; one cycle: 98°C for 30 s – 35 cycles: 98°C for 15 s, 58°C for 30 s, 72°C for 5 min – 1 cycle: 72°C for 2 min. PCR primers and parameters for PTEN-3’UTR SpeI-BstXI fragment: [PTEN-3’UTR SpeI-BstXI forward primer: 5’-CACTTATTTTACTAGTTTTCAATCATAATACCTG-3’; PTEN-3’UTR SpeI-BstXI reverse primer: 5’-TTGAAGACACCAAATTTCTGGAAAAAAAAACC-3’]; 1 cycle: 98°C for 30 s – 35 cycles: 98°C for 15 s, 58°C for 30 s, 72°C for 1 min – 1 cycle: 72°C for 2 min. PCR products were gel purified and a 1:3 vector to insert ratio (0.02 pmoles: 0.06 pmoles) was used for the Gibson Assembly reactions (New England BioLabs, cat# E5510S) according to manufacturer’s instructions (50°C, 15 min). The assembly reaction was transformed into chemically competent E. coli (New England BioLabs, cat# C3040I) according to manufacturer’s instructions, except 1 hr phenotypic expression and plating temperatures were performed at 30°C. A positive clone was verified by sequencing. Additional methods are available at https://osf.io/9stbg/.
PTEN 3’UTR transfection and quantitative PCR
Request a detailed protocolDU145 cells were seeded at 3.5 × 105 cells per well in 60 mm plates and grown overnight. The next day cells were washed once with phosphate buffered saline (Sigma-Aldrich, cat# D8537) before transfection using Effectene (Qiagen, cat# 301425) according to manufacturer’s instructions, or left untransfected. 1 µg plasmid (pCMV (empty vector) or pCMV-PTEN-3’UTR) was mixed with EC to a final volume of 150 µl followed by an addition of 8 µl of Enhancer, mixed for 1 s and then incubated at 25°C for 5 min. 25 µl of Effectene transfection reagent was added to the DNA-Enhancer sample and vortexed for 10 s before incubation at room temperature for 10 min. ~0.6 ml of growth medium was added to the transfection complex and mixed before added dropwise to dishes containing cells. 6 hr after transfection growth medium was replaced. 24 hr after transfection, total RNA was extracted and qPCR was performed as described above in ‘siRNA transfection and quantitative PCR’. Data files are available at https://osf.io/9etxj/.
PTEN 3’UTR transfection and crystal violet proliferation assay
Request a detailed protocolDU145 cells were seeded and transfected as described above in ‘PTEN 3’UTR transfection and quantitative PCR’ above. 6 hr after transfection cells were plated at 8,000 cell per well (in triplicate) in 12 well plates (enough for 6 days of measurements) with 2 ml of growth medium. Starting the day after plating (designated day 0), every 24 hr the crystal violet assay was performed as described in the Registered Report. Absorbance was recorded at 590 nm using SpectramaxPlus (Molecular Devices, Serial # P02528) and SoftMax Pro data acquisition and analysis software (RRID:SCR_014240), version 4.6. For each independent biological repeat, average absorbance (OD590) for each condition was normalized by dividing the average absorbance of each day to the average absorbance for day 0 to calculate relative cell number. Area under the curve (AUC) was calculated for each condition of each biological repeat. Raw data files are available at https://osf.io/qf7xa/.
Statistical analysis
Request a detailed protocolStatistical analysis was performed with R software (RRID:SCR_001905), version 3.5.1 (R Development Core Team, 2018). All data, csv files, and analysis scripts are available on the OSF (https://osf.io/yyqas/). Confirmatory statistical analysis was pre-registered (https://osf.io/2evzy) before the experimental work began as outlined in the Registered Report (Khan et al., 2015). Data were checked to ensure assumptions of statistical tests were met. When described in the results, the Bonferroni correction, to account for multiple tests, was applied to the alpha error or the p-value. The Bonferroni corrected value was determined by dividing the uncorrected value (0.05) by the number of tests performed. Although the Bonferroni method is conservative, it was accounted for in the power calculations to ensure sample size was sufficient. A meta-analysis of a common original and replication effect size was performed with a random effects model and the metafor R package (Viechtbauer, 2010) (https://osf.io/9yh6p/). The original study data was extracted a priori from the published figures by estimating the value reported. The extracted data was published in the Registered Report (Khan et al., 2015) and was used in the power calculations to determine the sample size for this study.
Data availability
Request a detailed protocolAdditional detailed experimental notes, data, and analysis are available on OSF (RRID:SCR_003238) (https://osf.io/yyqas/; Pandya et al., 2019). This includes the R Markdown file (https://osf.io/v3cag/) that was used to compose this manuscript, which is a reproducible document linking the results in the article directly to the data and code that produced them (Hartgerink, 2017).
Deviations from registered report
Request a detailed protocolThe first protocol of the Registered Report was conducted, but it was identified after results were obtained that the si-miR-19b and si-miR-20a reagents listed in the Registered Report and used in the experiment were incorrect and thus are not included in this manuscript. The catalog numbers listed were for microRNA hairpin inhibitors not microRNA mimics. The original study does not list the catalog numbers and only lists the reagents as si-miR-19b or si-miR-20a. The expected result of reduced PTEN levels following overexpression of miR-19b or miR-20a that has been observed previously (e.g., Luo et al., 2013; Poliseno et al., 2010; Tian et al., 2013) was not observed, which lead to the reevaluation of the reagent sources. Results obtained from using the inhibitors are available at https://osf.io/fjdtn/. The fifth and sixth protocol of the Registered Report (results presented in Figures 4,5) used a plasmid that overexpressed PTEN 3’UTR that was generated as part of this replication attempt while the Registered Report indicated the plasmid would be shared by the original lab. The reason to remake the plasmid was because the original lab did not respond to our multiple follow up requests to share the plasmid with us following acceptance of the Registered Report. Details of how the plasmid was made are described in the ‘PTEN 3’UTR plasmid generation’ section of the Materials and methods and the plasmid was deposited in Addgene (plasmid# 97204; RRID:Addgene_97204) for the research community to access. Additional materials and instrumentation not listed in the Registered Report, but needed during experimentation are also listed above.
Data availability
Additional detailed experimental notes, data, and analysis are available on OSF (RRID:SCR_003238) (https://osf.io/yyqas/; Pandya et al., 2018). This includes the R Markdown file (https://osf.io/v3cag/) that was used to compose this manuscript, which is a reproducible document linking the results in the article directly to the data and code that produced them (Hartgerink, 2017).
-
Open Science FrameworkStudy 1: Replication of Poliseno et al., 2010 (Nature).
References
-
A high content assay to assess cellular fitnessCombinatorial Chemistry & High Throughput Screening 17:12–24.https://doi.org/10.2174/13862073113169990056
-
A FTH1 gene:pseudogene:microRNA network regulates tumorigenesis in prostate cancerNucleic Acids Research 46:1998–2011.https://doi.org/10.1093/nar/gkx1248
-
PTENP1/miR-20a/PTEN Axis contributes to breast Cancer progression by regulating PTEN via PI3K/AKT pathwayJournal of Experimental & Clinical Cancer Research 38:256.https://doi.org/10.1186/s13046-019-1260-6
-
Expression of human prostatic acid phosphatase correlates with androgen-stimulated cell proliferation in prostate Cancer cell linesJournal of Biological Chemistry 273:5939–5947.https://doi.org/10.1074/jbc.273.10.5939
-
DataStudy 1: replication of Poliseno et al., 2010 (Nature)Open Science Framework.https://doi.org/10.17605/OSF.IO/YYQAS
-
SoftwareR: A language and environment for statistical computingR Foundation for Statistical Computing, Vienna, Austria.
-
NIH Image to ImageJ: 25 years of image analysisNature Methods 9:671–675.https://doi.org/10.1038/nmeth.2089
-
Effects of cell seeding density on real-time monitoring of anti-proliferative effects of transient gene silencingJournal of Biological Research-Thessaloniki 23:20.https://doi.org/10.1186/s40709-016-0057-4
-
Overexpression of long noncoding RNA PTENP1 inhibits cell proliferation and migration via suppression of miR-19b in breast Cancer cellsOncology Research Featuring Preclinical and Clinical Cancer Therapeutics 26:869–878.https://doi.org/10.3727/096504017X15123838050075
-
The ultimate qPCR experiment: producing publication quality, reproducible data the first timeTrends in Biotechnology 37:761–774.https://doi.org/10.1016/j.tibtech.2018.12.002
-
Replication in Prevention SciencePrevention Science 12:103–117.https://doi.org/10.1007/s11121-011-0217-6
-
Conducting Meta-Analyses in R with the Meta for packageJournal of Statistical Software 36:i03.https://doi.org/10.18637/jss.v036.i03c
-
Divergent activity of the pseudogene PTENP1 in ER-Positive and Negative Breast CancerMolecular Cancer Research 16:78–89.https://doi.org/10.1158/1541-7786.MCR-17-0207
-
Pseudogene PTENP1 functions as a competing endogenous RNA to suppress clear-cell renal cell carcinoma progressionMolecular Cancer Therapeutics 13:3086–3097.https://doi.org/10.1158/1535-7163.MCT-14-0245
Article and author information
Author details
Funding
Laura and John Arnold Foundation
- Reproducibility Project: Cancer Biology
The funder had no role in study design, data collection and interpretation, or the decision to submit the work for publication.
Acknowledgements
The Reproducibility Project: Cancer Biology would like to thank Laura Poliseno (Institute of Clinical Physiology-Italian National Research Council), Leonardo Salmena (University of Toronto), and Pier Paolo Pandolfi (Beth Israel Deaconess Cancer Center) for sharing critical protocol information during preparation of the Registered Report. We would also like to thank ProNovus Bioscience, LLC for assistance in generating the PTEN 3’UTR plasmid and Dale Cowley and Kumar Pandya, TransViragen, Inc, for conducting the knockdown experiments (specifically the cell growth assay, Western blot, and preparation of RNA for qPCR) as well as feedback on this manuscript. We thank the following companies for generously donating reagents to the Reproducibility Project: Cancer Biology; American Type and Tissue Collection (ATCC), Applied Biological Materials, BioLegend, Charles River Laboratories, Corning Incorporated, DDC Medical, EMD Millipore, Harlan Laboratories, LI-COR Biosciences, Mirus Bio, Novus Biologicals, Sigma-Aldrich, and System Biosciences (SBI).
Copyright
© 2020, Kerwin et al.
This article is distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use and redistribution provided that the original author and source are credited.
Metrics
-
- 2,103
- views
-
- 112
- downloads
-
- 7
- citations
Views, downloads and citations are aggregated across all versions of this paper published by eLife.
Download links
Downloads (link to download the article as PDF)
Open citations (links to open the citations from this article in various online reference manager services)
Cite this article (links to download the citations from this article in formats compatible with various reference manager tools)
Further reading
-
- Cancer Biology
The partial success of a study to reproduce experiments that linked pseudogenes and cancer proves that understanding RNA networks is more complicated than expected.
-
- Cancer Biology
Investigating reproducibility in preclinical cancer research.