Introduction

Oncology Letters

1792-1074 1792-1082

D.A. Spandidos

10.3892/ol.2018.8650

OL-0-0-8650

Articles

Critical factors for lentivirus-mediated PRDX4 gene transfer in the HepG2 cell line

Aznan

Afiah Nasuha

* Abdul Karim

Norwahidah

Wan Ngah

Wan Zurinah

Jubri

Zakiah

Department of Biochemistry, National University of Malaysia Medical Centre, Kuala Lumpur 56000, Malaysia

Correspondence to: Dr Zakiah Jubri, Department of Biochemistry, National University of Malaysia Medical Centre, Jalan Yaacob Latiff, Bandar Tun Razak, Cheras, Kuala Lumpur 56000, Malaysia, E-mail: zakiah.jubri@ppukm.ukm.edu.my *

Contributed equally

07 2018

07 05 2018

16 1 73 82 23022017 04122017

2018

This is an open access article distributed under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.

Optimization of critical factors affects transduction efficiency and is able to reduce reagent consumption. The present study aimed to determine the optimum transduction conditions of small hairpin (sh)RNA against peroxiredoxin 4 (PRDX4) in the HepG2 cell line. Cell viability assays were conducted based on serum condition, incubation time, polybrene concentration and antibiotic dose selection. Non-targeting control shRNA was transduced into HepG2 cells in a 5-fold serial dilution, and colonies positive for green fluorescent protein were counted using ImageJ software. Reverse transcription-quantitative polymerase chain reaction and western blot analysis were performed to validate PRDX4 expression. The optimum cell density for transduction was 5.0×10³ cells/well in 96-well plates to achieve 40 to 50% confluency the following day. The transduction media consisted of 10% fetal bovine serum (FBS) and 12 µg/ml polybrene, and was used to dilute lentiviral particles at a functional titer of 4.9×10⁵ TU/ml for multiplicity of infection (MOI) of 20, 15 and 10, for 24 h of incubation. Selection with 7 µg/ml puromycin was performed in transduced cells. shRNA 3 was revealed to inhibit PRDX4 mRNA and protein expression. In conclusion, PRDX4 was successfully silenced in 5.0×10³ HepG2 cells cultured with 10% FBS and 12 µg/ml polybrene, at a 4.9×10⁵ TU/ml functional titer for MOI of 20, 15 and 10.

optimization critical factors transduction peroxiredoxin 4 HepG2

Introduction

Transduction is the process of introducing small hairpin RNA (shRNA) sequences that are encoded in viral DNA into cells via viral vector. Upon binding to the cell, the viral genome is delivered into the cytoplasm, and Dicer protein enzymatically cleaves the short form of the shRNA from the viral origin. Then, the shRNA intermediate is imported into the host cell nucleus, where it is stably integrated into the host genome and interacts with several proteins to form an RNA-induced silencing complex (RISC). RISC silences the target gene by recognizing the corresponding mRNA sequences, and causing their degradation (1). With each cellular division, the integrated virus is replicated and passed on to the daughter cells, thus ensuring continued expression of the targeted sequence throughout the population. shRNAs are 19–22 bp double-stranded RNA, and are complementary to specific targets (2).

Cancer cell lines are commonly used to study carcinogenesis, potential biomarkers and alternative interventions, as they are homogenous and their supplies are unlimited. The present study used HepG2, which is a hepatoblastoma cell line (3). The HepG2 cell line has been misidentified as hepatocellular carcinoma cell line in previous scientific reports (4). However, the misidentification will not affect the outcome of the present study because it aims to provide a general guideline to optimize lentiviral transduction in a cell, and is not specific to either hepatocellular carcinoma or hepatoblastoma. In the present study, HepG2 was used as a model to silence a gene using the general guidelines mentioned. Comparison of the outcome in hepatocellular carcinoma and hepatoblastoma is beyond of the scope of the present study.

The development of genetic manipulation in the HepG2 cell line is challenging, with transfection methods resulting in inefficient transduction of the cells. As an alternative, lentiviral vectors and cationic polymers, including polybrene, have been used to increase transduction efficiency in the HepG2 cell line (5,6). HepG2 cells are of interest because previous studies have demonstrated that γ-tocotrienol treatment increases peroxiredoxin 4 (PRDX4) gene expression in HepG2 cells (7) and this gene may act as a sensitive marker of oxidative stress in liver injury (8). These studies suggested that PRDX4 may be involved in mechanisms that protect against oxidative stress, which remain unclear. This gap in knowledge requires elucidation at the molecular level in order to determine the function of PRDX4. Transduction is a useful approach to determine PRDX4 function, allowing modification of its expression in different conditions.

Several critical factors need to be considered in order to achieve specific and efficient transduction (9–11). These include cell density, polybrene concentration, serum condition, incubation time and puromycin antibiotic selection dosage (12–15). Functional titers and multiplicity of infection (MOI) determination further help to optimize shRNA delivery into the cells. In addition, ideal shRNA vector construction and design, which are crucial to control shRNA expression, also influence the transduction efficiency. The cells will suffer cytotoxicity and unwanted side effects if shRNA expression is too high, whereas transfection will be suboptimal if shRNA expression is too low. Significant progress has been made in predicting which shRNA vectors and target sequences are the most effective at reducing gene expression (16,17).

At present, the only way to measure the efficiency of specific shRNA target sequences is by direct experimentation. Variation in cell susceptibility to transduction is one of the major challenges in determining ideal conditions for high efficiency of gene transfer events (18,19). Thus, optimization of each transduction step is recommended to ensure the transduction conditions to fine-tune shRNA expression. The ability to control shRNA expression levels is important as silencing of the targeted gene contributes to cell survival and development (20). Thus, the present study was performed to determine the optimum conditions of PRDX4-shRNA transduction in HepG2 cells, and to determine the critical factors needed to ensure successful silencing.

Materials and methods <sec> <title>Cell line

HepG2 cells (American Type Culture Collection, Manassas, VA, USA) were cultured in complete culture media (CCM): Earle's modified Eagle's medium (Hyclone; GE Healthcare Life Sciences, Logan, UT, USA) containing 4 mM L-glutamine, 0.1 mM minimum essential medium (MEM) and non-essential amino acids, supplemented with 10% fetal bovine serum (FBS; Biowest USA, Riverside, MO, USA) in a humidified 37°C incubator containing 5% CO₂. HepG2 cells with <10 passages were used for subsequent experiments.

shRNA sequence and design

The pGIPZ lentiviral vector of 11.8 kb size (GE Healthcare Dharmacon Inc., Lafayette, CO, USA) harbors a reporter and a puromycin resistance gene. The encoded reporter gene is translated into a green fluorescent protein (GFP). The lentiviral vector is controlled by the immediate-early cytomegalovirus (CMV) promoter (Fig. 1). HepG2 cells were transduced with three individual shRNA clones against PRDX4 (NM_006406.1): sequence 1 (cat. no. 370039), sequence 2 (cat. no. 370042) and sequence 3 (cat. no. 200074) (GE Healthcare Dharmacon Inc.). Non-targeting negative control shRNA (cat. no. RHS4346), consisting of a random sequence and a positive control GAPDH-shRNA lentivirus (cat. no. RHS4372), were used as a control (GE Healthcare Dharmacon Inc.). The sequences are listed in Table I.

Optimization of basic transduction conditions

HepG2 cells were seeded at a density of 5×10³, 7.5×10³ and 10×10³ cells/well in a final volume of 100 µl CCM in two 96-well plates, repeated in triplicate for each cell density, and incubated in a humidified 37°C incubator with 5% CO₂ overnight. Cell density was observed using an inverted microscope (CK 40; Olympus Corporation, Tokyo, Japan) at 24 h post-transfection. Cell density that reached 40–50%, confluency was selected to be used in subsequent experiments and cell densities that resulted in >50% confluency were excluded. Transduction media (TM) with serum was freshly prepared, and consisted of a 1:1 ratio of Dulbecco's modified Eagle's medium (DMEM; Gibco; Thermo Fisher Scientific, Inc., Waltham, MA, USA) to MEM (Hyclone; GE Healthcare Life Sciences), 10% FBS and range of polybrene concentrations (0, 2, 4, 6, 8, 10, 12 and 14 µg/ml; Merck KGaA, Darmstadt, Germany). Culture media was discarded and 50 µl TM with and without serum and the aforementioned range of polybrene concentrations was added to each well. A total of 100 µl CCM with 10% FBS was added to the well with TM and 10% FBS 6 h after the initial addition of TM, whereas 100 µl CCM with 15% FBS was added to each well that contained TM without FBS. The same procedure was repeated for the second plate following incubation for 24 h at 37°C in a humidified atmosphere containing 5% CO₂. A cell viability assay was conducted after 24 h of CCM addition.

The viability assay was conducted by adding 120 µl of a Cell Titer 96^® aQueous One Solution reagent (Promega Corporation, Madison, WI, USA) that contains a MTS reagent diluted in CCM medium (20 µl MTS/100 µl CCM) in a 96-well for 2 h at 37°C. The purple formazan crystals were dissolved and the viability was analyzed at a wavelength of 490 nm using a microplate reader (EnSpire; PerkinElmer, Inc., Waltham, MA, USA). Three individual experiments were performed.

Determination of cytotoxicity

HepG2 cells were plated at a density of 5×10³ cells/well into a 96-well plate in triplicate, and reached 40–50% confluency the following day. A stock solution of 10 mg/ml puromycin (Santa Cruz Biotechnology, Inc., Dallas, TX, USA) was reconstituted with 50 mM dimethyl sulfoxide (Merck KGaA, Darmstadt, Germany). A working concentration range of 1–10 µg/ml was used. Puromycin stock solution was diluted using CCM to concentrations of 1.5, 3.0, 5.0, 7.0 and 10.0 µg/ml. Culture media were discarded, and 100 µl of each puromycin concentration was added to each well. Media containing the selection antibiotic for each concentration was replaced every 2–3 days for up to 7 days. Cell viability assay was performed as aforementioned once per day until day 7 to determine the visual toxicity effect on HepG2 cells. Three independent experiments were performed.

Determination of functional titer and MOI range

To establish the functional titer of lentiviral particles in HepG2 cells, cells were plated at a density of 7×10⁴ cells/well in 24-well plates in duplicate, and were permitted to reach 40 to 50% confluency by culturing overnight in humidified 37°C incubator with 5% CO₂. The TM consisted of a 1:1 ratio of DMEM and MEM, 10% FBS and 12 µg/ml polybrene, and was freshly prepared. Culture medium was removed and 225 µl TM was added to each well of the 24-well plate. Non-targeted negative control lentiviral particles were diluted to 5-fold serial dilutions (5, 25, 125, 625, 3,125, 15,625, 78,125 and 390,625 fold) in a flat-bottom 96-well plate with TM as a diluent, as previously described (3). This dilution range was according to the manufacturer's protocol. The diluted viral stock was incubated at room temperature for 10 to 20 min prior to the addition of 25 µl diluted lentiviral particles to the plates. Following incubation for 24 h, 100 µl CCM was added to the wells. GFP expression in the HepG2 cells was observed under a fluorescence microscope (Evos XL Core Imaging System; Thermo Fisher Scientific, Inc.) 48 h after transduction with the pGIPZ lentivirus. To ensure maximum accuracy and to compensate for multiple transduction events per cell, the titers were calculated only from transductions with dilution factors resulting in <25% transduced cells. In addition, the number of GFP-positive colonies were counted in duplicate, for two wells infected with two consecutive dilutions. GFP-positive colonies were counted at ×10 magnification for 3 to 5 random fields using ImageJ software (version 1.41; National Institutes of Health, Bethesda, MD, USA).

Functional titer was determined using the following formula: [493 (number of GFP colonies) × 25 (non-targeting control dilution)]/[0.025 ml (volume of diluted lentiviral particles used)]=4.9×10⁵ TU/ml. The functional titer of the non-targeting control was stated in the certificate of analysis provided by the manufacturer. This functional titer was used in the calculation of the volume of lentiviral particles required to infect HepG2 cells at the desired MOI.

HepG2 cell transduction

Three control groups and three shRNA sequences were established. Each group was set-up in technical triplicate wells. The control group consisted of HepG2 cells with TM, the positive control consisted of HepG2 cells and GAPDH-shRNA lentivirus, and the negative control consisted of HepG2 cells and non-targeting-shRNA lentivirus. HepG2 cells were cultured in a 96-well plate at a density of 5×10³ cells/well, reached 40–50% confluency following 24 h incubation at 37°C and underwent transduction using optimized optimal conditions. The lentiviral particles of sequences 1, 2 and 3 were diluted at 4.9×10⁵ TU/ml functional titer for MOI of 20, 15 and 10 with TM consists of 1 MEM: 1 DMEM, 10% FBS and 12 µg/ml polybrene (Merck KGaA, Darmstadt, Germany).

The volume of lentivirus required was calculated using the following formula: i) [5×10³ (number of cells seeded) × MOI 20]/[4.9×10⁵ TU/ml (functional titer of HepG2 cells)]=lentiviral volume, and ii) Lentiviral volume (µ1) ×7=final volume of lentiviral stock (µ1).

The lentiviral volume was multiplied to 7 to allow 3 volumes for triplicate wells of MOI 20, 3-fold dilution to achieve MOI 15, and 10, 5 and 1 volume for liquid overage during pipetting. The final volume lentiviral stock was calculated for MOI 20. Serial dilutions were performed for MOI 15, 10 and 5 from the MOI 20 stock. The diluted lentiviral particles were incubated at room temperature between 10 and 20 min. In total, 50 µl diluted virus particles were added at the indicated MOIs (20, 15, 10 and 5) and the cells was incubated at 37°C. After 24 h, 100 µl CCM with no virus particles was added, and the cells were incubated for an additional 48 h at 37°C for GFP expression. The cells were harvested using trypLE (Gibco; Thermo Fisher Scientific, Inc.) and centrifuged at 500 × g for 10 min at room temperature. The supernatant was discarded, the pellet was resuspended with 1 ml selection media (MEM, 10% FBS and 7 µg/ml puromycin) then, cultured in T25 culture flasks (Merck KGaA). Cells were maintained at 37°C in a humidified atmosphere containing 5% CO₂. Selection media was replaced every ~2–3 days. The selection media was used for subsequent experiments to ensure that only stably transduced cell were cultured.

Reverse transcription-quantitative polymerase chain reaction (qPCR) analysis

Stably silenced cells from each control and shRNA group were lysed using TRIzol reagent (Gibco: Thermo Fisher Scientific, Inc.) and the RNA was extracted according to the manufacturer's protocol. The extracted RNA was quantified using the NanoDrop 1000 spectrophotometer (NanoDrop Technologies; Thermo Fisher Scientific, Inc.). Subsequently, 1 µg total RNA was used as the template for cDNA synthesis, which was performed using a QuantiNova Reverse Transcription kit (Qiagen, Inc., Valencia, CA, USA) according to the manufacturer's protocol. cDNA was amplified using the QuantiNova SYBR Green real time-PCR kit (Qiagen, Inc.) and the BioRad iQ5 Multicolour Real-time PCR machine (Bio-Rad Laboratories, Inc., Hercules, CA, USA). GAPDH was used as an internal control. Three independent experiments were performed on the same group. The primer sequences for GAPDH (NM_001256799.2) forward, 5′-TCCCTGAGCTGAACGGGAAG-3′, and reverse, 5′-GGAGGAGTGGGTGTCGCTGT-3′, yielded a 245 bp product and the primer sequences for the PRDX4 gene (NM_006406.1) forward, 5′-GCAAAGCGAAGATTTCCAAG-3′ and reverse, 5′-GGCCAAATGGGTAAACTGTG-3′ yielded a 217 bp product.

The PCR conditions were as follows: Initial melting at 95°C for 2 min; followed by 30 cycles at 95°C for 5 sec; 60°C for 10 sec; and 95°C for 1 min. The final extension was performed at 55°C for 10 min. Analysis of the melting curve for the primers was conducted to confirm the specificity of the PCR product, and the threshold cycle (Cq) value for triplicate reactions was averaged. The relative expression of PRDX4 mRNA for each sample was calculated as follows: ΔCq=Cq (sample)-Cq (GAPDH), ΔΔCq (sample)=ΔCq (sample)-ΔCq (calibrator). The fold changes in mRNA were calculated through relative quantification (2^−ΔΔCq) (21).

Western blot analysis

Following selection, transduced cell were washed three times with cold 1X phosphate buffered saline and lysed using lysis buffer comprised of protease inhibitors (Promega Corporation, Madison, WI, USA) and RIPA buffer (Merck KGaA). The cell lysates were suspended in 200 µl lysis buffer and were incubated on ice for 30 min. Following this, the cell lysate was centrifuged at 18,506 × g for 30 min at 4°C and the supernatant was collected. The extracted proteins were quantified using the Bradford protein assay (Bio-Rad Laboratories, Inc.). Total protein (40 µg per lane) was treated with SDS sample buffer and heated at 95°C for 2 min. The protein samples were separated on a 12% SDS-polyacrylamide gel and transferred onto polyvinylidene difluoride membranes (GE Healthcare Life Sciences). The membranes were blocked with 5% skimmed milk diluted with Tween-20 phosphate buffered saline (TPBS; 998 ml 1X phosphate buffered saline, 2 ml Tween-20) for 1 h at room temperature. Then, the membranes were incubated overnight with primary mouse monoclonal anti-PRDX4 (1:500; cat no. ab68344; Abcam, Cambridge, UK) and mouse monoclonal anti-β-actin (1:1,000; cat no. ab8224; Abcam) at 4°C. The membranes were then washed with TPBS at intervals of 5 min. Following this, the membranes were incubated with polyclonal secondary horseradish peroxidase-conjugated goat anti-mouse immunoglobulin G (1:2,500; cat no. ab97023; Abcam) for 1 h at room temperature, followed with three washes with TPBS at 5 min intervals. The bands were visualized using enhanced chemiluminescence reagents (Advansta, Inc., Menlo Park, CA, USA) and visualized on a Gel Documentation System (GE Healthcare Life Sciences). Three independent experiments were performed.

Statistical analysis

GraphPad Prism 5 software (GraphPad Software, Inc., La Jolla, CA, USA) was used for data processing. Comparisons between groups were performed using one-way analysis of variance followed by the Tukey's multiple range test. Quantitative data are expressed as the mean ± standard deviation. Figures were generated using GraphPad Prism 5. P<0.05, P<0.01 and P<0.001 were considered to indicate a statistically significant difference.

Results <sec> <title>Optimization of basic transduction conditions

Factors measured included cell density, incubation time, serum conditions and polybrene concentration. The cell densities used were 5.0×10³, 7.5×10³ and 10.0×10³ cells/well, and cell confluence was observed under a light microscope on the following day. The results revealed that densities of 7.5×10³ and 10.0×10³ cells/well resulted in >50% confluence, while a density of 5.0×10³ cells/well did not. Therefore, 5.0×10³ cells/well was the selected HepG2 cell density that was used for subsequent experiments. There was no significant difference when comparing 6 and 24 h of incubation for groups with and without FBS in TM. However, as presented in Fig. 2, cells incubated in TM without FBS for 6 and 24 h had decreased cell viability compared with cells incubated in TM with 10% FBS for 6 and 24 h, with increasing polybrene concentration. The absence of serum caused polybrene to significantly reduce cell viability earlier, at 10, 12 and 14 µg/ml (P<0.001) for the two incubation times. In comparison, when cells were incubated with TM with 10% FBS, cell viability was only significantly reduced by 14 µg/ml polybrene (P<0.05). The highest polybrene concentration which did not affect cell viability during incubation in TM with 10% FBS was 12 µg/ml. Incubation times of 6 and 24 h for TM with 10% FBS did not significantly affect cell viability. An increased duration of exposure to lentivirus may increase cell transduction efficiency, so an incubation time of 24 h was selected. Thus, a density of 5×10³ cells/well in a 96 well plate, 12 µg/ml polybrene in TM with 10% FBS and a 24 h incubation time were selected as optimal transduction conditions for HepG2 cells.

Titration of puromycin

HepG2 cells were subjected to increasing doses of puromycin from day 3 to 7. The optimal dose was selected. As presented in Fig. 3, the viability of HepG2 cells decreased with increasing doses of puromycin. Based on a cell viability assay, HepG2 cells exhibited decreased viability (up to 90% of cell death) at day 7 in response to 7 and 10 µg/ml puromycin. The optimal puromycin concentration is the lowest dose that will kill 90–99% non-selected HepG2 cells within 7 days, therefore a dose of 7 µg/ml puromycin was selected. The transduced cells were selected and cultured in selection media that consisted of base media, 10% FBS and 7 µg/ml puromycin to maintain the stable cell lines generated.

Functional titer and MOI range determination

Serial dilutions (5-fold) of the non-targeting lentiviral control were transduced into HepG2 cells in duplicate, and the number of colonies positive for GFP were used to calculate functional titer. GFP-positive colonies were counted at the low dilution of 25X and 125X, while no GFP colonies were generated for dilutions of 625X to 390,635X (Fig. 4A). A functional titer of 4.9×10⁵ lentiviral particles was obtained. The optimized functional titer and transduction conditions were used to transduce a GAPDH positive control, a non-targeting negative control and three PRDX4-shRNAs with different sequences at MOI 20, 15, 10 and 5. The results revealed that no GFP-positive colonies were generated from the control group for all MOIs, whereas for the GAPDH positive control group and non-targeting negative control group, GFP was generated for all MOIs (Fig. 4B). Transduced colonies decreased as MOI decreased, and only MOI of 20, 15 and 10 were positive for GFP when transduced with shRNA 1, 2 and 3. Therefore, MOI 20, 15 and 10 were used to transduce HepG2 cells for subsequent experiments. An overlay of transduced cells with generated GFP colonies and a comparison of transduced and non-transduced HepG2 cells is presented in Fig. 4C. The transduced cells have clumpy morphology and are slower growing compared with non-transduced cells.

PRDX4 gene expression

Following transduction for 48 h, shRNA 1 (P<0.01) and 2 (P<0.01) was significantly reduced PRDX4 mRNA expression, up to 8-fold, whereas shRNA 3 resulted in a 5-fold reduction compared with the control group (P<0.05; Fig. 5A). Expression in the non-targeting control transduction and control groups was not significantly different. PRDX4 mRNA expression levels in the negative control, shRNA 1, shRNA 2 and shRNA 3 groups were 1.03±0.12, 0.22±0.11, 0.26±0.11 and 0.52±0.26, respectively. PRDX4 mRNA levels were the lowest in the cells treated with PRDX4-shRNA 1 and shRNA 2 compared with the control group.

PRDX4 protein expression

Transduction with shRNA 1 (P<0.05), 2 (P<0.01) and 3 (P<0.001) for 48 h resulted in a significant reduction of PRDX4 protein expression (5, 6 and 8-fold, respectively) compared with the control group (Fig. 5B). PRDX4 protein expression levels for the non-targeting control, shRNA 1, shRNA 2 and shRNA 3 were 0.96±0.26, 0.57±0.31, 0.43±0.16 and 0.25±0.13. Compared with the control group, PRDX4 protein expression levels were lowest in the cells transduced with PRDX4-shRNA 3.

Discussion

Stable cell lines were generated when GIPZ lentiviral DNA integrated into the host genome and permanently expressed the shRNA as the cells divided. Several factors affected transduction efficiency, including cell density, polybrene concentration, incubation time, serum condition and antibiotic selection dose. The best optimization method should consist of at least two potential shRNA sequences that silence the target gene. This would provide control for off-target knockdowns, since it is unlikely for different sequences to produce the same off-target effects, which increasing the potential for successful gene knockdown (22). Furthermore, optimized shRNA constructs require a relatively low copy number of lentiviral particles, resulting in fewer off-target effects and a reduction in unwanted silencing effects (23). A good experimental design consists of a positive control, negative control and untreated control to further validate the significant and specific silencing effect (24,25). GFP colonies were generated when the GIPZ GAPDH positive control was transduced into HepG2 cells (Fig. 4B). This confirmed that the plasmid construct was successfully delivered into the cells and activated the RNA interference pathway without affecting cell viability or function (26). Well-characterized positive controls target the housekeeping genes that are abundantly expressed in the cells. This demonstrated that expression was neither affected by experimental treatments nor fluctuated with the cell cycle. One of the major problems faced by shRNA delivery in mammalian systems is the probability of triggering off-target effects, inconsistent phenotypes and cellular toxicity due to interactions between sense and antisense shRNA strands (27–29). Thus, GIPZ non-targeting negative controls (NTC) are important to distinguish sequence-specific silencing from off-target effects. The NTC sequence does not match with known mammalian genes, having at least three or more mismatches against any gene as determined via nucleotide alignment. An ideal NTC sequence produces a minimal effect on cell viability, and mRNA and protein expression levels should remain comparable with the control (Fig. 5A and B). When the NTC is comparable with the control group, it is possible to conclude that the gene knockdown is specific and that any downstream effect can be attributed to silencing of the target gene. Furthermore, it is possible to measure transduction efficiency by assessing the number of GFP-positive colonies following transfection with NTC shRNA (Fig. 4A). Untreated control determines the baseline level of cell viability and target gene level compared with NTC control (Fig. 5A and B).

Efficient shRNA delivery into cells is paramount. There should be enough shRNA production to create gene knockdown at a concentration that does not over activate the RISC complex or result in toxic effects to the cells. Vector-based shRNA transduction allows the long-term downregulation of target genes and but may have variable transduction efficiency, since it is cell type-dependent. Lentiviral vectors, enhanced promoters and GIPZ shRNA are elements that serve essential functions in the maximization of efficient shRNA production in HepG2 cells, and may increase the probability of transduction events occurring (30,31). Lentiviral-based vectors with human (h)CMV enhancer have been reported to infect up to 95% of HepG2 cells and stably integrate into the host genome for long-term transgene expression (32–34). In addition, lentiviral vectors result in low toxicity and high stability with no effect on cell phenotype or cell type (35,36). GIPZ shRNA design is based on native microRNA-30 primary transcripts to enable processing by endogenous RNA interference pathways, resulting in specific silencing and minimized cellular toxicity (37,38). In addition, the presence of selectable markers, which are a puromycin resistance gene and a GFP gene reporter, assist in selecting a stable cell line with an incorporated vector and expression of the inserted gene to be cultured. To achieve successful gene silencing, screening >2 shRNA fragments and scaling down to a single fragment which regulates high levels of transcription may increase the silencing effect. Silencing activity does not only depend on the shRNA being 100% complementary to the target gene, but also on the location where shRNA binding occurs. Different shRNA fragments have random integration sites and will generate a variety of dependent expression levels (39). The present study was initiated by the construction of three different shRNA sequences targeting PRDX4, and later transduced into HepG2 cells using polybrene to improve the efficiency. Finally, one shRNA demonstrated the required effect.

Cell density, polybrene concentration, incubation time and transduction media conditions should be systematically examined for every cell type and, once optimized, must be kept constant in all future experiments to ensure reproducible results. Previous studies have stated that HepG2 cells line maintained the same expression of drug metabolizing enzymes compared with that in primary hepatocytes until passage 16 (40,41). Healthy, actively dividing cells take up foreign nucleic acids more efficiently than quiescent cells (42). Thus, it is advisable to select cell lines with <16 passages that are actively dividing for this approach. It is recommended to maintain the cells at least 24 h prior initiating the transduction procedure, to ensure they are in optimum physiological condition for transduction. A cell confluency >50% is considered to be over-confluent and may cause contact inhibition, resulting in poor uptake of nucleic acids, thus decreasing the expression of the transduced gene. However, too few cells in the culture may result in poor growth without cell-to-cell contact (43). In the present study, the transduction process took at least 96 h for the cells to grow, thus, maintaining a standard seeding protocol from each experiment will ensure that optimal confluence is reliably achieved. Generally, a density of 5×10³ cells/well seeded in a 96-well plate reached ~40–50% confluence after 24 h, providing optimized results for the HepG2 cell line.

A previous study reported that the addition of polybrene to cells in serum-free media with enhanced lentiviral transduction efficiency by 2–10-fold (11). However, serum free media and high concentration of polybrene may reduce cell viability due to the toxic conditions. Thus, MTS assays were conducted on non-transduced cells to determine the effect of transduction media condition on cell viability. FBS provides a higher transduction efficiency compared with bovine calf serum (9). However, while the presence of serum in culture media boosts cell growth, it also increases the chance of endotoxin contamination. It is important to control for variability among the different brands of serum, as the quality can significantly affect cell growth and transduction results. In contrast, heat inactivation of FBS did not exert a discernible effect on the efficiency of lentiviral transduction (9). The results obtained demonstrated that an absence of serum in the culture media reduced HepG2 cell viability following incubation for 6 and 24 h, compared with cells incubated in the presence of serum (Fig. 2). Thus, TM with 10% FBS is used to transduce HepG2 cells. Cellular and viral lipid membranes possess a net-negative charge. The addition of cationic polymers, including polybrene, to TM has been suggested since these polymers bind to the cell surface and neutralize the surface charge, increasing transduction efficiency by enhancing adsorption of the lentiviral particles. High polybrene concentrations increase the probability of transduction events, however, these may also reduce cell viability. Thus, the optimal concentration of polybrene needs to be determined to avoid toxicity to the cells. The highest polybrene concentration of TM with 10% FBS which did not significantly reduced HepG2 cell viability was 12 µg/ml. If the polybrene concentration failed to induce significant cellular toxicity after 24 h incubation, this incubation time may be used for subsequent transductions (44). Incubation for 6 and 24 h with 10% FBS did not affect cell viability in the present study. In addition, an increased duration of exposure to the lentivirus will maximize lentiviral infection, increasing transduction efficiency (12).

A GIPZ lentiviral construct that encodes for a puromycin resistance gene will only allow the transduced cells to grow in culture with puromycin, which will kill non-transduced cells by interrupting their protein synthesis. Construction of a kill curve is recommended since puromycin concentration is cell type-dependent. The kill curve construction involved a dose-response experiment where non-transduced cells were subjected to increasing concentrations of puromycin to determine the minimum antibiotic concentration needed to kill all cells over the course of 3–7 days. Puromycin reached optimum effectiveness after 48 h of selection and, in general, it took 7 days for a single transduced colony to form a population of transduced HepG2 cells. The selection medium, which was comprised of base medium, 10% FBS and the optimized puromycin concentration (7 µg/ml) was changed daily for a week. This eliminated potentially toxic substances produced by the dying cells and maintained the concentration of the antibiotic at a constant level during the selection process. Antibiotic dosage is considered low when minimal visual toxicity is apparent even after 7 days of antibiotic exposure, while the antibiotic dose is considered high when visual toxicity is evident within the first 2–3 days of antibiotic selection. The optimal dose of puromycin was 7 µg/ml, which was the lowest antibiotic concentration to kill 90–99% of cells (Fig. 3) after 7 days of antibiotic selection.

The most critical factor to determine for successful lentiviral transduction is the functional titer. The functional titer is referred as smallest transduction unit of virus capable of infecting susceptible cells and expressing the transgene per ml solution (TU/ml). Serial dilution of non-targeting lentiviral stock helped to determine the optimal concentration of functional lentiviral required in HepG2 cells. The functional titer was 4.9×10⁵ TU/ml, and was calculated from a number of GFP transduced colonies developed after 48 h transduction. An optimized functional titer only requires a relatively small volume of lentiviral particles to transduce cells at a constant ratio, referred as multiplicity of infection (MOI), and thus increases transduction efficiency. One of the factors that affects the functional titer is shRNA production. A potent promoter and vector are essential to produce sufficient amounts of shRNA in HepG2 cells, in order to maximize transduction efficiency. Low shRNA production will cause transduction to be suboptimal, and higher levels of shRNA production may inhibit transduction. Functional titer is also cell type-dependent. Each cell has different level of susceptibility towards lentiviral infection (45) and an actively dividing cell line would give a higher transduction rate than non-dividing types of cell (46). One of the major advantages of the lentiviral delivery method is the ability to control the number of viral genomes that enter HepG2 cells by adjusting the MOI. It is important to note that different cell types may require different MOIs for knockdown of the target gene. The sensitivity of cells to lentiviral infection is MOI-dependent: The higher the MOI, the higher the transduction efficiency. To obtain optimal expression, a range of MOIs from 20, 15, 10 and 5 were tested on HepG2 cells in the present study. The results obtained revealed that only MOI 20, 15 and 10 result in significant levels of cell transduction (Fig. 4B). Constant MOIs of 20, 15 and 10 were used to transduce the HepG2 cells with a 4.9×10⁵ TU/ml functional titer. Working in the smallest well format and volume helps achieve higher MOI, by using fewer lentiviral particles to increase transduction efficiency.

Although shRNA functions at the mRNA level, ultimately it is the reduction in protein level that causes the observed phenotype. Therefore, validation of gene silencing was assessed by measuring the corresponding protein and gene reduction using western blot analysis and qPCR (47). Gene silencing mediated by mRNA may occur at three stages, including pre-translational, co-translational, and post-translational steps, which exert direct and indirect effects on translation machinery (48). This justifies the non-corresponding effect of PRDX4 silencing on protein reduction at the mRNA level measured following transfection with each shRNA sequence, suggesting that PRDX4 expression was not regulated at the mRNA level. mRNA levels have been demonstrated to not always be associated with protein expression levels, for example those observed in human liver tissue (49,50). These studies emphasized the probabilities of post-transcriptional or post-translational modifications, and additional unknown regulatory mechanisms and signaling. Furthermore, different shRNA integration sites may affect the level of expression. The use of lentiviral vectors provides a novel method by which HepG2 cells may be stably genetically manipulated, with minimal effects on the differentiated hepatic phenotype. Lentiviral infection has previously been demonstrated to not affect hepatic hallmarks, including the expression of the nuclear receptors CXADR, Ig-like cell adhesion molecule, nuclear receptor subfamily 1 group I member 2, retinoid C receptor α, and hepatocyte nuclear factor 4α, or albumin expression. Furthermore, HepG2 cells demonstrated that transgene expression is preserved through cell division and is retained for the duration of the culture period (36).

In conclusion, the optimal transduction conditions, which include cell density, polybrene concentration, transduction media condition, incubation time and selective antibiotic dose, were identified to produce a HepG2 cell line with stably silenced PRDX4. The results demonstrated that shRNA 3 significantly suppressed PRDX4 expression at the mRNA and protein level, and this shRNA was therefore used in subsequent experiments. This model may be used to test the effect of nutritional interventions on hepatoblastoma, and may lead to improved understanding of treatment strategies for hepatoblastoma and also for patients with liver cancer in general.

Acknowledgements

The present study was funded by National University of Malaysia Medical Centre (grant no. FF-2016-063) and the Ministry of Higher Learning under the Fundamental Research Grant Scheme (grant no. UKM-AP-2014-024).

Competing interests

The authors declare that they have no competing interests.

References 1

Manjunath

Haoquan

Sandesh

Premlata

Lentiviral delivery of short hairpin RNAs

Adv Drug Deliv Rev617327452009

10.1016/j.addr.2009.03.004

19341774

Aigner

Gene silencing through RNA interference (RNAi) in vivo: Strategies based on the direct application of siRNAs

J Biotechnol12412252006

10.1016/j.jbiotec.2005.12.003

16413079

López-Terrada

Cheung

Finegold

Knowles

HepG2 is a hepatoblastoma-derived cell line

Hum Pathol40151215152009

10.1016/j.humpath.2009.07.003

Pang

RTK

Poon

TCW

Wong

Lai

PBS

Wong

NLY

Chan

CML

JSW

Chan

ATC

Sung

JJY

Comparison of protein expression patterns between hepatocellular carcinoma cell lines and a hepatoblastoma cell line

Clin Proteomics13133312004

10.1385/CP:1:3-4:313

Le Bihan

Chèvre

Mornet

Garnier

Pitard

Lambert

Probing the in vitro mechanism of action of cationic lipid/DNA lipoplexes at a nanometric scale

Nucleic Acids Res39159516092011

10.1093/nar/gkq921

21078679

Cesaratto

Vascotto

D'Ambrosio

Scaloni

Baccarani

Paron

Damante

Calligaris

Quadrifoglio

Tiribelli

Tell

Overoxidation of peroxiredoxins as an immediate and sensitive marker of oxidative stress in HepG2 cells and its application to the redox effects induced by ischemia/reperfusion in human liver

Free Radic Res392552682005

10.1080/10715760400029603

15788230

Sazli

Abdul Rahman F

Jubri

Rahman

Abdul M

Karsani

Top

Md AG

Ngah

Wan WZ

Gamma-tocotrienol treatment increased peroxiredoxin-4 expression in HepG2 liver cancer cell line

BMC Complement Altern Med15642015

10.1186/s12906-015-0590-y

25886747

Ito

Takahashi

Ihara

Tsukamoto

Fujii

Ikeda

Measurement of peroxiredoxin-4 serum levels in rat tissue and its use as a potential marker for hepatic disease

Mol Med Rep63793842012

10.3892/mmr.2012.935

22684688

Denning

Das

Guo

Kappes

Hel

Optimization of the transductional efficiency of lentiviral vectors: Effect of sera and polycations

Mol Biotechnol533083142013

10.1007/s12033-012-9528-5

22407723

Logan

Nightingale

Haas

Cho

Pepper

Kohn

Factors influencing the titer and infectivity of lentiviral vectors

Hum Gene Ther159769882004

10.1089/hum.2004.15.976

15585113

Davis

Rosinski

Morgan

Yarmush

Charged polymers modulate retrovirus transduction via membrane charge neutralization and virus aggregation

Biophys J86123412422004

10.1016/S0006-3495(04)74197-1

14747357

Morgan

LeDoux

Snow

Tompkins

Yarmush

Retrovirus infection: Effect of time and target cell number

J Virol69699470001995

7474118

Andreadis

Lavery

Davis

Le Doux

Yarmush

Morgan

Toward a more accurate quantitation of the activity of recombinant retroviruses: Alternatives to titer and multiplicity of infection

J Virol74125812662000

10.1128/JVI.74.7.3431-3431.2000

10627536

Dokka

Toledo

Shi

Rojanasakul

High-efficiency gene transfection of macrophages by lipoplexes

Int J Pharm206971042000

10.1016/S0378-5173(00)00531-7

11058814

Zhang

Metharom

Jullie

Ellem

Cleghorn

West

Wei

The significance of controlled conditions in lentiviral vector titration and in the use of multiplicity of infection (MOI) for predicting gene transfer events

Genet Vaccines Ther262004

10.1186/1479-0556-2-8

15291957

Taxman

Livingstone

Zhang

Conti

Iocca

Williams

Lich

Ting

Reed

Criteria for effective design, construction, and gene knockdown by shRNA vectors

BMC Biotechnol672006

10.1186/1472-6750-6-7

16433925

Takasaki

Kotani

Konagaya

An effective method for selecting siRNA target sequences in mammalian cells

Cell Cycle37907952004

10.4161/cc.3.6.892

15118413

Luria

Cell susceptibility to viruses

Ann N Y Acad Sci618528551955

10.1111/j.1749-6632.1955.tb42542.x

13340592

Yang

Bailey

Baltimore

Wang

Targeting lentiviral vectors to specific cell types in vivo

Proc Natl Acad Sci USA10311479114842006

10.1073/pnas.0604993103

16864770

Gupta

Schoer

Egan

Hannon

Mittal

Inducible, reversible, and stable RNA interference in mammalian cells

Proc Natl Acad Sci USA101192719322004

10.1073/pnas.0306111101

14762164

Healthcare

Technical manual: GIPZ Lentiviral shRNA

Thermo Sci2015

Livak

Schmittgen

Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) method

Methods254024082001

10.1006/meth.2001.1262

11846609

Moore

Guthrie

Huang

Taxman

Short hairpin RNA (shRNA): Design, delivery, and assessment of gene knockdown

Methods Mol Biol6291411582010

20387148

Svoboda

Off-targeting and other non-specific effects of RNAi experiments in mammalian cells

Curr Opin Mol Ther92482572007

17608023

Huppi

Martin

Caplen

Defining and assaying RNAi in mammalian cells

Mol Cell171102005

10.1016/j.molcel.2004.12.017

15629712

Whither RNAi

Nat Cell Biol54894902003

10.1038/ncb0603-490

12776118

Goncz

Gruenert

Colosimo

Expression vector system and a method for optimization and confirmation of DNA delivery and quantification of targeting frequency

Journal2005

Feng

Nie

Thakur

Chi

Zhao

Longmore

A multifunctional lentiviral-based gene knockdown with concurrent rescue that controls for off-target effects of RNAi

Genomics Proteomics Bioinformatics82382452010

10.1016/S1672-0229(10)60025-3

21382592

Jackson

Linsley

Noise amidst the silence: Off-target effects of siRNAs?

Trends Genet205215242004

10.1016/j.tig.2004.08.006

15475108

Snøve

JrHolen

Many commonly used siRNAs risk off-target activity

Biochem Biophys Res Commun3192562632004

10.1016/j.bbrc.2004.04.175

15158470

Matveeva

Nechipurenko

Rossi

Moore

Saetrom

Ogurtsov

Atkins

Shabalina

Comparison of approaches for rational siRNA design leading to a new efficient and transparent method

Nucleic Acids Res35e632007

10.1093/nar/gkm088

17426130

ter Brake

't Hooft

Liu

Centlivre

von Eije

Berkhout

Lentiviral vector design for multiple shRNA expression and durable HIV-1 inhibition

Mol Ther165575642008

10.1038/sj.mt.6300382

18180777

Nasri

Karimi

Farsani

Allahbakhshian M

Production, purification and titration of a lentivirus-based vector for gene delivery purposes

Cytotechnology66103110382014

10.1007/s10616-013-9652-5

24599752

Nash

Jamil

Maguire

Alexander

Lever

Hepatocyte-specific gene expression from integrated lentiviral vectors

J Gene Med69749832004

10.1002/jgm.591

15352070

Nishitsuji

Ikeda

Miyoshi

Ohashi

Kannagi

Masuda

Expression of small hairpin RNA by lentivirus-based vector confers efficient and stable gene-suppression of HIV-1 on human cells including primary non-dividing cells

Microbes Infect676852004

10.1016/j.micinf.2003.10.009

14738896

Rao

Vorhies

Senzer

Nemunaitis

siRNA vs. shRNA: Similarities and differences

Adv Drug Deliv Rev617467592009

10.1016/j.addr.2009.04.004

19389436

Zamule

Strom

Omiecinski

Preservation of hepatic phenotype in lentiviral-transduced primary human hepatocytes

Chem Biol Interact1731791862008

10.1016/j.cbi.2008.03.015

18468591

Lim

Lau

Garrett-Engele

Grimson

Schelter

Castle

Bartel

Linsley

Johnson

Microarray analysis shows that some microRNAs downregulate large numbers of target mRNAs

Nature4337697732005

10.1038/nature03315

15685193

Lin

Khvorova

Fesik

Shen

Defining the optimal parameters for hairpin-based knockdown constructs

RNA13176517742007

10.1261/rna.599107

17698642

McIntyre

Arndt

Gillespie

Mak

Fanning

A comparison of multiple shRNA expression methods for combinatorial RNAi

Genet Vaccines Ther992011

10.1186/1479-0556-9-9

21496330

Westerink

Schoonen

Phase II enzyme levels in HepG2 cells and cryopreserved primary human hepatocytes and their induction in HepG2 cells

Toxicol In Vitro21159216022007

10.1016/j.tiv.2007.05.014

17716855

Wilkening

Bader

Influence of culture time on the expression of drug-metabolizing enzymes in primary human hepatocytes and hepatoma cell line HepG2

J Biochem Mol Toxicol172072132003

10.1002/jbt.10085

12898644

Prijic

Sersa

Magnetic nanoparticles as targeted delivery systems in oncology

Radiol Oncol451162011

10.2478/v10019-011-0001-z

22933928

Song

Yang

Construction of shRNA lentiviral vector

N Am J Med Sci25986012010

10.4297/najms.2010.2598

22558575

Wotherspoon

Dolnikov

Symonds

Nordon

Susceptibility of cell populations to transduction by retroviral vectors

J Virol78509751022004

10.1128/JVI.78.10.5097-5102.2004

15113891

Johnston

Gasmi

Lim

Elder

Yee

Jolly

Campbell

Davidson

Sauter

Minimum requirements for efficient transduction of dividing and nondividing cells by feline immunodeficiency virus vectors

J Virol73499150001999

10233961

Orang

Valinezhad A

Safaralizadeh

Kazemzadeh-Bavili

Mechanisms of miRNA-mediated gene regulation from common downregulation to mRNA-specific upregulation

Int J Genomics20149706072014

25180174

Zeng

Cullen

Efficient processing of primary microRNA hairpins by Drosha requires flanking nonstructured RNA sequences

J Biol Chem28027595276032005

10.1074/jbc.M504714200

15932881

Anderson

Seilhamer

A comparison of selected mRNA and protein abundances in human liver

Electrophoresis185335371997

10.1002/elps.1150180333

9150937

Schwanhäusser

Busse

Dittmar

Schuchhardt

Wolf

Chen

Selbach

Global quantification of mammalian gene expression control

Nature4733373422011

10.1038/nature10098

21593866

Figure 1.

Schematic drawings of the shRNA construct. The PRDX4 shRNA was cloned into the pGIPZ vector under control of hCMV. shRNA, short hairpin RNA; LTR, long terminal repeat; RRE, rev response element; hCMV, human cytomegalovirus promoter; GFP, green fluorescent protein; IRES, internal ribosomal entry sites; Puro^R, puromycin; WRPE, woodchuck hepatitis post-transcriptional regulatory element; SIN, self-inactivating.

Figure 2.

Basic transduction condition. HepG2 cell viability in transduction media in the absence and presence of serum at 6 and 24 h, as the polybrene concentration increases. Data are presented as the mean ± standard deviation, and each group consists of a technical triplicate for 3 biological replicates. a, P<0.05 vs. TM 10% FBS 6 h; b, P<0.05 vs. TM 10% FBS 24 h; c, P<0.05 vs. TM without FBS 6 h and d, P<0.05 vs. TM without FBS 24 h. TM, transduction media; FBS, fetal bovine serum.

Figure 3.

Kill curve determination. HepG2 kill curves were constructed from day 3–7 using a range of puromycin concentrations. Data are presented as the mean ± standard deviation, and each group consists of technical triplicates for 3 biological replicates. *P<0.05 vs. 0 µg, **P<0.01 vs. 0 µg and ***P<0.001 vs. 0 µg.

Figure 4.

Green fluorescent protein expression of HepG2 cells under a fluorescence microscope, EVOS XL. (A) Functional titer determination. The experiment was designed in duplicate with lentiviral particle were to 5-fold serial dilutions as follows: ×25, ×125, ×625, ×3125, ×15625 and ×390625. Image was taken by fluorescent microscope, EVOS XL (magnification, ×40). (B) MOI range of HepG2 cells. Image was taken by fluorescent microscope, EVOS XL (magnification, ×40). (C) Overlaid image of transduced and non-transduced HepG2 cells (magnification, ×10). The scale bar represents 400 µm. MOI, multiplicity of infection; shRNA, small hairpin ribonucleic acid.

Figure 5.

Validation of PRDX4 expression. (A) Fold change of PRDX4 mRNA expression. (B) Fold change of PRDX4 protein expression. Data are presented as the mean ± standard deviation normalized to the control group. NTC refers to a non-targeting control, control refers to non-transduced cells, and each group consists of a technical triplicate for 3 biological replicates. *P<0.05, **P<0.01 and ***P<0.001. PRDX4, peroxiredoxin 4; NTC, non-targeting control; shRNA, small hairpin ribonucleic acid.

Table I.

Sequences of PDX4 shRNA and non-targeting negative control shRNA.

shRNA	Sequence (5′-3′)
GAPDH-shRNA positive control
Sense	ATGGTTTACATGTTCCAAT
Antisense	ATTGGAACATGTAAACCAT
Non-targeting negative control
Sense	ATCTCGCTTGGGCGAGAGTAAG
Antisense	CTTACTCTCGCCCAAGCGAGAG
shRNA PRDX4 sequence 1
Sense	GAGCTGAAGTTAACTGATT
Antisense	AATCAGTTAACTTCAGCTC
shRNA PRDX4 sequence 2
Sense	AGCTGAAGTATTTCGATAA
Antisense	TTATCGAAATACTTCAGCT
shRNA PRDX4 sequence 3
Sense	ACCTGGTAGTGAAACAATA
Antisense	TAATTGTTTCACTACCAGGT

shRNA, small hairpin ribonucleic acid, PRDX4, peroxiredoxin 4.