Kinome-Wide Screening with Small Interfering RNA Identified Polo-like Kinase 1 as a Key Regulator of Proliferation in Oral Cancer Cells

Oral squamous cell carcinoma (OSCC) is one of the major leading causes of cancer-related death worldwide, with limited effective markers for diagnosis and therapy, which has caused a low overall survival rate in the past decades. Kinases play important roles in tumor development and malignancy in various types of cancer. However, little is known about the role of kinases in OSCC cells. In this study, an arrayed kinome small interfering RNA (siRNA) library was used to screen oral cancer cell lines and counter assayed with normal fibroblast cells to identify the genes required for cancer cell proliferation. We found that polo-like kinase 1 (PLK1) was one of the most potent genes required for OSCC cell proliferation. The knockdown of PLK1 with a siRNA or antisense oligonucleotide (ASO) consistently diminished cyclin-B1 (CCNB1) expression/phosphorylation and the G2-M phase transition. Similar effects were observed in cells treated with the PLK1 kinase inhibitor BI6727. Besides, The Cancer Genome Atlas (TCGA) analysis revealed that PLK1 was elevated in tumor tissues and associated with short survival in patients with OSCC. We also found that PLK1 expression was highly correlated with the expression of its downstream effector, CCNB1, in patients with OSCC. Coexpression of the two genes resulted in a poor prognosis of OSCC patients, particularly those in the advanced stages of OSCC. Taken together, our results suggest that PLK1 might be a diagnostic or therapeutic marker for OSCC.


Introduction
Oral squamous cell carcinoma (OSCC) is one of the major leading causes of cancer death worldwide, with increasing incidence, particularly in South Asia [1]. In addition to betel chewing  Cell viability was measured by a CellTiter-Glo assay (Promega, Madison, WI, USA). (C) Cells were transfected with the top 13 ranked siRNAs (as listed) that reduced cell viability in both SAS (white) and TW2.6 (black) cells. The mRNA level in each gene was determined by real-time PCR to confirm the knockdown efficiency of siRNA using scramble siRNA (Ctrl) as normalized controls. The fold change of mRNA level in each siRNA knockdown is indicated above each bar. (D) The siRNAs were further counter-assayed with normal human gingival cells (HGF-1). The selective effects of silencing three genes, namely, PLK1, CHEK1, and WEE1, are shown. (E) The expression of the three genes in OSCC patients is presented as reads per kilobase of transcript per million mapped reads (RPKM) to compare its transcription level between tumor tissues and adjacent normal tissues according to the TCGA (The Cancer Genome Atlas) dataset. * p < 0.05, ** p < 0.01, *** p < 0.001, tumor tissues vs. the adjacent normal tissues. (F) Kaplan-Meier plots were used to evaluate the gene association with overall survival in patients with OSCC. (G) Kaplan-Meier plots were used to evaluate the gene association with disease-free survival in patients with OSCC.

Western Blot for Protein Expression
Human oral cancer cells were briefly rinsed in PBS and lysed with RIPA buffer (1% NP40, 50 mM Tris-Cl, pH 7.5, 150 mM NaCl, 0.25% sodium deoxycholate, 0.1% SDS, and protease inhibitor cocktail). The cell lysates were resolved by SDS-PAGE (sodium dodecyl sulfate-polyacrylamide gel electrophoresis) and transferred electrophoretically onto nitrocellulose membranes. The membrane was blocked with 5% skim milk and then incubated with the primary antibodies, including anti-PLK (ab17056, Abcam, Eugene, OR, USA), anti-phospho-CCNB1 (ab60986, Abcam, Eugene, OR, USA), and anti-actin (A5441, Sigma-Aldrich, St. Louis, MO, USA), at 4°C overnight. The proteins were probed with an horseradish peroxidase (HRP)-labeled secondary antibody and detected with ECL reagent. The membrane was scanned and analyzed for protein expression with Odyssey Imaging Systems (LI-COR Biosciences, Lincoln, NE, USA).

Clonogenic Assay
Human cancer cells were seeded into six-well plates at a density of 10 3 cells/well in the presence of inhibitors or the ASO or siRNA against PLK. Cells were then washed and cultured in complete media, and fresh media was provided every 3 days for 2 weeks. The cell colonies were fixed with 2% paraformaldehyde and stained with 20% ethanol containing 0.25% crystal violet at room temperature for 30 min [8]. The stained cells were washed with PBS 3 times to observe colonies. Colonies over 1 mm were counted, and the ratio of the number of colonies formed between cells treated with inhibitors or an ASO against PLK was calculated with Prism 5 (San Diego, CA, USA).

Cell Viability
The cell viability assay was performed using a CellTiter-Glo Luminescent Cell Viability Assay Kit (Promega, Madison, WI, USA). Briefly, 5 × 10 5 to 7 × 10 5 cells/mL were cultured in sterile 96-well plates for 24 to 48 h, and then 100 µL of CellTiter-Glo reagent was added to lyse the cells for 10 min. The luminescence signal was measured using a Fluoroskan Ascent FL reader (Thermo Fisher Scientific, Carlsbad, CA, USA).

Flow Cytometry for Cell Cycle Analysis
The knockdown cells were washed with PBS and fixed with 75% ethanol at −20 • C overnight, as previously described [9]. Fixed cells were washed with PBS containing 1% FBS and further stained with propidium iodide (50 µg/mL, Sigma-Aldrich, St. Louis, MO, USA) and RNase A (25 µg/mL) on ice for 30 min. The stained cells were analyzed for cell cycle proportion by using FACScan (Becton Dickinson, San Diego, CA, USA).

Statistical Analysis
The gene expression data and clinical information of OSCC were obtained from the TCGA dataset. The Kruskal-Wallis one-way ANOVA test was used to evaluate the differential gene expression in tumor adjacent normal (TAN) tissues and tumor tissues in OSCC data obtained from the TCGA database. The gene expression levels between TAN tissues and tumor tissues were analyzed by the Wilcoxon signed-rank test. The gene expression level was divided into a high and low group according to receiver operating characteristic (ROC) curve. The Kaplan-Meier method was used to analyze cumulative survival curves, and a survival curve analysis was performed using the log-rank test. The Cox proportional hazards model was used to evaluate the impact of gene expression on survival using factors identified as significant in the univariate analysis as covariates. The association between cell differentiation and the relative gene expression levels in tumor tissues compared with those in the paired TAN tissues of individual OSCC patients with different AJCC (American Joint Committee on Cancer) pathological stages was determined by Fisher's exact test. A value of p < 0.05 was considered statistically significant and has been marked as bold in each table.

High-Throughput Screening for Potential Targets in OSCC Cells
To determine whether any kinase is crucial for the survival of OSCC cells, human tongue cancer SAS cells and buccal mucosa TW2.6 cells were transfected with a kinome siRNA library for 72 h, and the viable cells were measured with CellTiter-Glo according to the cellular ATP levels ( Figure 1A,B). Genes in which cell proliferation was less than 60% in both SAS and TW2.6 cells after knockdown were selected as candidate genes for further validation ( Figure 1C). Thirteen genes were selected after screening: CDC2L5, WEE1, DDR1, PLK1, CHEK1, PLK4, AURKA, MAP3K11, TTBK2, TXK, FES, TNK2, and PAK6. Human gingival fibroblasts (HGF-1) are normal oral cells and can be used as counter cells to eliminate gene hits that are also required for normal cell physiology ( Figure 1D). Silencing WEE1, PLK1, or CHEK1 could also reduce the gene expression in HGF cells. The viability results showed that knockdown of the genes selectively reduced cancer cell viability without affecting normal HGF-1 cells, suggesting that these three genes might be worthy of follow up. We further evaluated the expression of candidate genes in OSCC patients with the TCGA dataset, which consists of corresponding normal tissues from patients (normal, n = 30), primary tumors (n = 315), and metastatic tumors (n = 2) ( Figure 1E). The expression of PLK1 and CHEK1 was significantly higher in tumor tissues than in normal tissues, whereas WEE1 expression was significantly lower in tumor tissues than that in normal tissues ( Figure 1E). Moreover, patients with high PLK1 expression had shorter overall survival than those with low PLK1 expression (p < 0.001, Figure 1F). However, CHEK1 expression was not significantly associated with overall survival (p = 0.119). The expression of either PLK1 (p = 0.240) or CHEK1 (p = 0.210) had no significant correlation with disease-free survival ( Figure 1G).

Genetic Ablation of PLK1-Attenuated Oral Cancer Cell Proliferation
PLK1 is reportedly responsible for cyclin B1 (CCNB1) phosphorylation to promote the G 2 -M phase transition in the cell cycle [10]. To further determine the effects of the siRNA against PLK1 on CCNB1 phosphorylation in oral cancer cells, SAS and TW2.6 cells were transfected with various concentrations of pooled siRNAs against PLK1, which target different gene loci from the original siRNA used in the primary screen. A low dose of pooled siRNAs against PLK1 (1 nM) effectively reduced the PLK1 protein level and the phosphorylation of CCNB1 at Ser 133 (Figure 2A,B). The long-term effects of the siRNA against PLK1 on the colony formation of oral cancer cells were examined with a clonogenic assay ( Figure 2C,D). Silencing PLK1 with the siRNA significantly suppressed colony formation in both SAS and TW2.6 oral cancer cells.
More interestingly, we designed different lengths of locked antisense oligonucleotides against PLK1 (ASO-PLK1-16 or ASO-PLK1-14) and examined their effects on the knockdown efficiency of PLK1 and the phosphorylation of CCNB1 ( Figure 3A). Although both antisense oligonucleotides at a concentration of 10 nM showed sufficient silencing effects on PLK1, ASO-PLK1-14 had better knockdown efficiency on PLK1 than did ASO-PLK1-16 ( Figure 3A). Accordingly, CCNB1 phosphorylation was decreased in oral cancer cells. Moreover, ASO-PLK1 significantly reduced the viability of SAS and TW2.6 cells ( Figure 3B). The long-term effects of ASO-PLK1 on cancer cell growth were inspected with a clonogenic assay ( Figure 3C,D). Similar to the knockdown efficiency, the suppressive effects of ASO-PLK1-14 on colony formation were stronger than those of ASO-PLK1-16. These results indicated that ASO-PLK1-14 might be more potent on silencing effects of PLK1 and growth inhibition in oral cancer cells.   The quantitative results are expressed as the mean ± SEM from three independent experiments (right panel). * p < 0.05, ** p < 0.01, *** p < 0.001 vs. the non-targeting control siRNA (siCtrl).

Pharmacological Ablation of PLK1-Attenuated Oral Cancer Cell Proliferation
To determine whether the kinase activity of PLK1 is involved in cancer cell proliferation, oral cancer cells were treated with the PLK1-specific inhibitor BI6727 to examine the CCNB1 expression/phosphorylation and cell proliferation ( Figure 4). BI6727 reduced CCNB1 expression and phosphorylation in oral cancer cells ( Figure 4A). BI6727 treatment inhibited cell viability and colony formation in SAS and TW2.6 cells in a dose-dependent manner ( Figure 4B-D). Besides, PLK1 inhibitors may induce a cell cycle arrest at the G2-M phase and apoptosis in cancer cells [11]. We further investigated the effects of BI6727 in the cell cycle of SAS and TW2.6 oral cancer cells ( Figure 4E). BI6727 largely caused a G2-M phase arrest in cell cycle progression, whereas it did not affect sub-G1 phase, suggesting that PLK1 inhibition-reduced cell proliferation might mainly occur through a cell cycle arrest at G2-M phase in oral cancer cells. The quantitative results are expressed as the mean ± SEM from three independent experiments (right panel). * p < 0.05, ** p < 0.01, *** p < 0.001 vs. the non-targeting control siRNA (siCtrl).

Pharmacological Ablation of PLK1-Attenuated Oral Cancer Cell Proliferation
To determine whether the kinase activity of PLK1 is involved in cancer cell proliferation, oral cancer cells were treated with the PLK1-specific inhibitor BI6727 to examine the CCNB1 expression/phosphorylation and cell proliferation ( Figure 4). BI6727 reduced CCNB1 expression and phosphorylation in oral cancer cells ( Figure 4A). BI6727 treatment inhibited cell viability and colony formation in SAS and TW2.6 cells in a dose-dependent manner ( Figure 4B-D). Besides, PLK1 inhibitors may induce a cell cycle arrest at the G 2 -M phase and apoptosis in cancer cells [11]. We further investigated the effects of BI6727 in the cell cycle of SAS and TW2.6 oral cancer cells ( Figure 4E). BI6727 largely caused a G 2 -M phase arrest in cell cycle progression, whereas it did not affect sub-G 1 phase, suggesting that PLK1 inhibition-reduced cell proliferation might mainly occur through a cell cycle arrest at G 2 -M phase in oral cancer cells.

The Association of PLK1 with Prognosis According to the Demographical and Clinicopathological Features of OSCC Patients
We observed that PLK1 expression was higher in tumor tissues than that in adjacent normal tissues of OSCC patients (Figure 1). The higher PLK1 expression was also correlated with shorter

The Association of PLK1 with Prognosis According to the Demographical and Clinicopathological Features of OSCC Patients
We observed that PLK1 expression was higher in tumor tissues than that in adjacent normal tissues of OSCC patients (Figure 1). The higher PLK1 expression was also correlated with shorter overall survival of OSCC patients (Figure 1). To evaluate the detailed association between PLK1 expression and OSCC, PLK1 expression was analyzed in OSCC patients with different demographical characteristics and pathological outcomes (Table 1). PLK1 expression was elevated in tumor tissues with moderate and poor differentiation compared to that in tumor tissues with good differentiation. We stratified the patients into different groups to examine the impact of PLK1 expression on overall survival according to the demographical and clinicopathological features of the patients ( Figure 5). The Kaplan-Meier analysis showed worse effects of PLK1 expression on overall survival in patients with certain demographical and clinicopathological features ( Figure 5), including sex (female: p = 0.040; male: p = 0.011), age (≤60: p = 0.043; >60: p = 0.005), moderate/poor differentiation (p = 0.007), and advanced AJCC pathological stages (p = 0.005). Moreover, the results were further adjusted by cell differentiation and AJCC pathological stage (Table 2). High PLK1 expression was significantly associated with poor overall survival in males ( Table 2, adjusted hazard ratio (AHR) = 1.64, p = 0.034) and elderly (>60 years: AHR = 1.64, p = 0.017) patients. High PLK1 expression was correlated with a worse prognosis in tumor tissues with both good (AHR = 4.32, p = 0.026) and moderate/poor (AHR = 1.57, p = 0.026) differentiation (Table 2). Moreover, high PLK1 expression was associated with unfavorable overall survival in patients with an advanced pathological stage ( Table 2, AHR = 1.67, p = 0.014), whereas it was correlated with unfavorable overall survival in patients with early T stage (T1 and T2, AHR = 2.51, p = 0.022) and in tumors without lymph node invasion (N0, AHR = 2.24, p = 0.023). High PLK1 expression was also associated with unfavorable overall survival in OSCC patients with (AHR = 2.12, p = 0.017) or without (AHR = 1.95, p = 0.029) postoperative radiation therapy. Nevertheless, the stratification results showed that PLK1 expression was not associated with disease-free survival in any patient groups based on clinicopathological features (Table 3). These results suggested that PLK1 expression might be involved in tumor progression and survival in OSCC patients, depending on demographical and clinicopathological features. overall survival of OSCC patients (Figure 1). To evaluate the detailed association between PLK1 expression and OSCC, PLK1 expression was analyzed in OSCC patients with different demographical characteristics and pathological outcomes (Table 1). PLK1 expression was elevated in tumor tissues with moderate and poor differentiation compared to that in tumor tissues with good differentiation. We stratified the patients into different groups to examine the impact of PLK1 expression on overall survival according to the demographical and clinicopathological features of the patients ( Figure 5). The Kaplan-Meier analysis showed worse effects of PLK1 expression on overall survival in patients with certain demographical and clinicopathological features ( Figure 5), including sex (female: p = 0.040; male: p = 0.011), age (≤60: p = 0.043; >60: p = 0.005), moderate/poor differentiation (p = 0.007), and advanced AJCC pathological stages (p = 0.005). Moreover, the results were further adjusted by cell differentiation and AJCC pathological stage (Table 2). High PLK1 expression was significantly associated with poor overall survival in males ( Table 2, adjusted hazard ratio (AHR) = 1.64, p = 0.034) and elderly (>60 years: AHR = 1.64, p = 0.017) patients. High PLK1 expression was correlated with a worse prognosis in tumor tissues with both good (AHR = 4.32, p = 0.026) and moderate/poor (AHR = 1.57, p = 0.026) differentiation (Table 2). Moreover, high PLK1 expression was associated with unfavorable overall survival in patients with an advanced pathological stage ( Table 2, AHR = 1.67, p = 0.014), whereas it was correlated with unfavorable overall survival in patients with early T stage (T1 and T2, AHR = 2.51, p = 0.022) and in tumors without lymph node invasion (N0, AHR = 2.24, p = 0.023). High PLK1 expression was also associated with unfavorable overall survival in OSCC patients with (AHR = 2.12, p = 0.017) or without (AHR = 1.95, p = 0.029) postoperative radiation therapy. Nevertheless, the stratification results showed that PLK1 expression was not associated with diseasefree survival in any patient groups based on clinicopathological features (Table 3). These results suggested that PLK1 expression might be involved in tumor progression and survival in OSCC patients, depending on demographical and clinicopathological features.

The Correlation of PLK1 and CCNB1 with Prognosis in Patients with OSCC
In addition to the phosphorylation effects of PLK1 on CCNB1, PLK1 binds to the DNA-binding domain of tumor protein p53 (TP53) to block its transcriptional activity, which may induce CCNB1 gene expression [12]. The knockdown of PLK1 indeed diminished CCNB1 expression in OSCC cells. To determine whether PLK1 expression is correlated with CCNB1 expression in patients with OSCC, Pearson's correlation was used to analyze gene expression in OSCC data from the TCGA dataset. Interestingly, PLK1 expression was highly correlated with CCNB1 expression ( Figure 6A, r = 0.769, p < 0.001). The Kaplan-Meier survival curve showed that the high coexpression of PLK1 and CCNB1 was correlated with shorter overall survival ( Figure 6B, p = 0.002), particularly in cells with moderate/poor differentiation ( Figure 6C, p = 0.014) and advanced pathological stages ( Figure 6D, p = 0.012). The association of high PLK1 and CCNB1 coexpression with disease-free survival is shown in Figure 6E (p = 0.017). Its unfavorable impacts on disease-free survival in certain types of OSCC patients were also observed, such as those with moderate/poor differentiation ( Figure 6F, p = 0.028) and advanced pathological stages ( Figure 6G, p = 0.022). Besides, the association of the coexpression level of PLK1 and CCNB1 in overall survival and disease-free survival was analyzed with univariate and multivariate Cox proportional hazards models ( Table 4). The patients with high coexpression levels of PLK1 and CCNB1 had worse overall survival (Table 4, crude hazard ratio (CHR) = 1.60, p = 0.016, AHR = 1.98, p = 0.002). These results implied that the coexpression of PLK1 and CCNB1 might be a potential diagnostic marker for OSCC.

Discussion
To date, there is almost no targeted therapy for patients with OSCC due to limited targets reported thus far. In this study, we employed a kinome siRNA library to screen potential oncogenic kinases required for the proliferation of OSCC cells and reported the following findings. First, silencing PLK1 with either a siRNA or ASO attenuated CCNB1 phosphorylation and blocked the proliferation of OSCC cells. Second, the PLK1 inhibitor diminished the expression/phosphorylation of CCNB1 and arrested the cell cycle at the G2-M phase. Third, the TCGA data analysis indicated that PLK1 expression was higher in tumor tissues than in adjacent normal tissues. High PLK1 expression was also associated with worse overall survival in OSCC patients with certain demographical and pathological features. Fourth, PLK1 expression was highly correlated with CCNB1 expression in OSCC patients. The coexpression of PLK1 and CCNB1 was significantly correlated with poor overall

Discussion
To date, there is almost no targeted therapy for patients with OSCC due to limited targets reported thus far. In this study, we employed a kinome siRNA library to screen potential oncogenic kinases required for the proliferation of OSCC cells and reported the following findings. First, silencing PLK1 with either a siRNA or ASO attenuated CCNB1 phosphorylation and blocked the proliferation of OSCC cells. Second, the PLK1 inhibitor diminished the expression/phosphorylation of CCNB1 and arrested the cell cycle at the G 2 -M phase. Third, the TCGA data analysis indicated that PLK1 expression was higher in tumor tissues than in adjacent normal tissues. High PLK1 expression was also associated with worse overall survival in OSCC patients with certain demographical and pathological features. Fourth, PLK1 expression was highly correlated with CCNB1 expression in OSCC patients. The coexpression of PLK1 and CCNB1 was significantly correlated with poor overall survival and disease-free survival. Thus, our results may suggest that coexpression of PLK1-CCNB1 is a good biomarker for patients with OSCC.
Synthetic nucleotides, including siRNAs and ASOs, have been used to knock down gene expression in a wide variety of experiments and clinical trials [13]. The siRNA is delivered as a double strand, and the passenger strand is removed by the argonaute of the RNA-induced silencing complex (RISC). The guide strand then primes the mRNA sequence, as ASO does for gene silencing. The specificity and efficacy of the siRNA depend on the sequence and chemical modifications [14]. Pooled siRNAs may reduce off-target effects due to the limited amount of every single siRNA. Thus, we began our screen with a pooled siRNA library (Thermo Fisher Scientific, Carlsbad, CA, USA) to identify candidate genes essential for the proliferation of OSCC cells. The top-ranked gene, PLK1, was further confirmed with different pooled siRNAs (Dharmacon, Lafayette, LO, USA) that contain different sequences and chemical modifications. Both pooled siRNAs against PLK1 efficiently blocked the proliferation of OSCC cells. Similar to a siRNA, an ASO-generated DNA-RNA hybrid can be degraded by RNase H. Also, an ASO may decrease gene expression via the attenuation of translation and RNA splicing [13]. The ASO against PLK1 also diminished the growth of OSCC cells, particularly in the short gapmer with eight bases in the central gap (ASO-PLK1-14). Our present study supports the notion that PLK1 is an essential gene for OSCC proliferation.
Our kinome siRNA library screening results showed that PLK1, CHEK1, and WEE1 were the top three selective genes required for the growth of OSCC cells. PLK1 expression is gradually increased and peaks at the M phase of the cell cycle, which activates CDC25, a phosphatase and activator of CDK1, to promote cell cycle progression at the G2-M phase [10]. In contrast to PLK1, WEE1 and CHEK1 are negative regulators in the G2-M phase transition. WEE1 is a tyrosine kinase that inhibits CDK1 by phosphorylating it at Tyr 15 and 14, which in turn arrests the cell cycle at the G 2 phase in cells during DNA damage [15]. WEE1 is also involved in homologous recombination DNA repair [15]. Moreover, CHEK1 is a serine/threonine kinase and a major downstream regulator of ataxia telangiectasia-mutated and Rad-3-related (ATR) for cell cycle arrest at the G2-M phase transition in cells in response to DNA damage [16]. CHEK1 phosphorylates Ser216 of CDC25 and triggers the proteasomal degradation of CDC25 [17]. Besides, CHEK1 phosphorylates PLK1 to promote its degradation in the proteasome, whereas CHEK1 can phosphorylate and activate WEE1 for cell cycle arrest at the G2-M phase [17]. Although our screening platform was based on two OSCC cell lines, and the functions of these three selective genes in G2-M phase may be different, our results implied that the G2-M phase transition might play a crucial role in OSCC cell proliferation. Nevertheless, the detailed mechanisms by which these genes regulate each other in OSCC cells under normal physiological conditions require further study.
Regarding the roles of the gene hits in cancer, PLK1 is overexpressed in numerous types of cancer, including lung cancer, breast cancer, hepatocellular carcinoma, head and neck cancer, cholangiocarcinoma, and uterine corpus endometrial carcinoma [10]. WEE1 is highly expressed in brain cancer, breast cancer, and melanoma [18], while CHEK1 expression is higher in the tumor tissues of breast cancer, colon cancer, and liver cancer [17]. The PLK1 inhibitor BI2536 and its derivative BI6727 inhibit tumor growth in vitro and in the clinical setting [19,20], suggesting that a PLK1 inhibitor could be a monotherapy for cancer treatment. In contrast, targeting WEE1 or CHEK1 sensitizes cancer cells to DNA-damaging drugs [21,22], supporting WEE1 and CHEK1 as potential targets and chemosensitizers for cancer therapy. However, our results showed that WEE1 expression was lower in tumor tissues than in adjacent normal tissues and that CHEK1 was not associated with shorter survival. Thus, the roles of WEE1 and CHEK1 in OSCC might need further verification.
Our current study showed that PLK1 expression was associated with tumorigenesis and the poor prognosis of OSCC patients. The siRNA against PLK1 selectively inhibited OSCC cell proliferation, implying that PLK1 could be a potential target for OSCC. Additionally, PLK1 expression is much higher in tumor tissues than in adjacent normal tissues in certain types of cancer, such as lung cancer (20.8-fold), cholangiocarcinoma (24.3-fold), and uterine corpus endometrial carcinoma (21.3-fold) [10]. Its expression is also higher in head and neck squamous cell carcinoma (4.2-fold). High PLK1 expression is associated with poor prognosis in head and neck squamous cell carcinoma [23]. Moreover, several PLK1 inhibitors have been tested in clinical trials for advanced solid tumors [24]. Our results indicated that a siRNA or ASO against PLK1 suppressed the proliferation of OSCC cells. These results suggested that the siRNA or ASO against PLK1 used in our study might be suitable for testing its efficacy in the cancer types mentioned above.

Conclusions
In conclusion, PLK1 is required for the G 2 -M phase transition in OSCC cells, likely through CCNB1 expression/phosphorylation. PLK1 expression or its coexpression with CCNB1 was highly correlated with a poor prognosis, particularly in OSCC patients with certain stages, supporting PLK1 could be a potential diagnostic marker or therapeutic target for OSCC patients in the future.