STK16 was found to be upregulated in colorectal cancer

To evaluate its role, we initially examined STK16 expression in colorectal cancer and normal colorectal tissue using TCGA databases. The results revealed a significant overexpression of STK16 in colorectal cancer compared to normal colorectal tissues (Fig. 1A-B). Subsequently, 31 pairs of colorectal cancer tissues and adjacent normal tissues were collected. IHC analysis demonstrated a substantial upregulation of STK16 in colorectal cancer (Fig. 1C-E), which was further validated by western blot results (Fig. 1F). Furthermore, an additional set of 63 colorectal cancer samples was subjected to IHC assays. The outcomes indicated that patients with higher T stage and clinical stage exhibited elevated STK16 expression levels (Fig. 1G-I). Additionally, patients were stratified based on STK16 expression, and Kaplan-Meier analysis revealed that those with higher STK16 expression had poorer clinical overall survival times (Fig. 1J). Similar findings were observed in Kaplan-Meier analysis for TCGA database of colorectal cancer (Fig. 1K). Additionally, the role of STK16 in other types of cancers was explored. The results demonstrated overexpression of STK16, and patients with higher STK16 expression levels had worse clinical prognoses in most types of cancer (Figure S1). Overall, these results suggest that STK16 may function as an oncogene in the progression of colorectal cancer.

Fig. 1

STK16 Upregulation in Colorectal Cancer. A, B. Investigation of STK16 expression levels in colorectal cancer using TCGA database. C. Representative IHC images of colorectal cancer tissues and adjacent matched normal tissues. D, E. Statistical analysis of STK16 expression levels in colorectal cancer tissues and adjacent matched normal tissues. F. Immunoblotting (IB) assays to assess STK16 expression in colorectal cancer tissues and adjacent matched normal tissues. G. Representative IHC images of colorectal cancer tissues. H, I. Statistical analysis of STK16 expression levels in colorectal cancer patients grouped by T stages (H) or clinical stages (I). J. Kaplan-Meier plotter to analyze overall survival time of colorectal cancer patients grouped by STK16 expression. K. Kaplan-Meier Plot drawn using TCGA database, with patients grouped by STK16 expression. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis was performed using Student’s t-test

STK16 overexpression was observed to promote the proliferation and metastasis of colorectal cancer

To investigate its role further, we utilized lentivirus to establish RKO and Lovo cells with stable ectopic expression of STK16. Western blots confirmed the successful construction of these cells (Fig. 2A). CCK8 and BrdU assays were conducted to evaluate whether the overexpression of STK16 affected colorectal cancer cell proliferation. The results indicated that cells with stable ectopic expression of STK16 exhibited enhanced proliferation ability (Fig. 2B-D). Considering the inevitability of distant metastasis in the progression of colorectal cancer, we also examined the impact of STK16 on cell colony formation and metastatic potential. Colony formation assays revealed that cancer cells with stable ectopic expression of STK16 displayed a more robust ability for colony formation (Fig. 2E-F). Furthermore, these cells exhibited higher migration and invasion abilities compared to control cancer cells (Fig. 2G-H). In summary, these findings confirm that the overexpression of STK16 significantly enhances the proliferation and metastatic capabilities of cancer cells.

Fig. 2

STK16 Overexpression Promoted Colorectal Cancer Progress In Vitro. A. IB assays validated the successful construction of identified cells. B-D. CCK8 (B) and Brdu (C, D) assays assessed the proliferation ability of colorectal cancer cells stably expressing vector or STK16. E, F. Colony formation assays assessed the colony formation ability of colorectal cancer cells stably expressing vector or STK16; Representative images (E) and statistical analysis (F) shown. G, H. Transwell assays assessed the migration and invasion ability of colorectal cancer cells stably expressing vector or STK16; Representative images (G) and statistical analysis (H) shown. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis used Student’s t-test

Loss of STK16 inhibited colorectal cancer cell proliferation and metastasis

To further affirm the biological function of STK16 in colorectal cancer proliferation and metastasis, we employed the Crisp-cas9 system to knock out STK16 in RKO and Lovo cancer cells (Fig. 3A). CCK8 assays confirmed that the loss of STK16 significantly hindered colorectal cancer cell proliferation (Fig. 3B). This finding was further supported by BrdU assays (Fig. 3C-D). Moreover, we demonstrated that STK16 knock-out markedly suppressed the colony formation, migration, and invasion abilities of cancer cells (Fig. 3E-H). In summary, these results provide evidence that STK16 plays a positive regulatory role in cancer cell proliferation and metastasis.

Fig. 3

Loss of STK16 Significantly Suppressed Colorectal Cancer Progress In Vitro. A. IB assays validated the successful construction of identified cells. B-D. CCK8 (B) and Brdu (C, D) assays assessed the proliferation ability of colorectal cancer cells stably expressing sgCtrl or sgSTK16. E, F. Colony formation assays assessed the colony formation ability of colorectal cancer cells stably expressing sgCtrl or sgSTK16; Representative images (E) and statistical analysis (F) shown. G, H. Transwell assays assessed the migration and invasion ability of colorectal cancer cells stably expressing sgCtrl or sgSTK16; Representative images (G) and statistical analysis (H) shown. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis used Student’s t-test

STK16 positively regulated MYC signaling by stabilizing MYC

We demonstrated that STK16 may function as an oncogene in colorectal cancer, positively correlating with cancer cell proliferation and metastasis. However, the detailed mechanism underlying STK16’s regulation of colorectal cancer progression remained unclear. To address this, we analyzed TCGA and GEO databases. GSEA analysis for TCGA database indicated that STK16 positively activated the MYC signaling pathway in both colon and rectal cancers (Fig. 4A). Similar results were observed in various GEO datasets (Figure S2A). We then examined the expression levels of c-MYC and its downstream genes (GLUT1 and CDK4) in colorectal cancer cells ectopically expressing STK16 or sgSTK16. Results revealed that STK16 overexpression significantly upregulated the expression of c-MYC, GLUT1, and CDK4, while silencing STK16 notably suppressed their expression levels (Fig. 4B and Figure S2B). Additionally, we demonstrated that STK16 WT, but not the enzyme-deficient mutant STK16 T198A, could upregulate c-MYC, GLUT1, and CDK4 expression (Wang et al. 2019a, b). Treatment with the STK16 inhibitor, STK16-IN-1, decreased c-MYC and GLUT1 expression (Figure S2C-E) (Liu et al. 2016). These findings indicated that STK16-mediated c-MYC expression depended on the enzyme activation of STK16. Interestingly, STK16 had no effect on the mRNA expression of c-MYC (Figure S2F-G), suggesting that STK16 might post-translationally regulate c-MYC expression. To explore potential post-translational regulation mechanisms, we considered autophagy-lysosome and ubiquitin-proteasome pathways. Inhibiting the autophagy-lysosome pathway with chloroquine (CQ) did not affect STK16-mediated c-MYC upregulation, while inhibiting the ubiquitin-proteasome pathway with MG132 abolished this effect (Fig. 4C). Further experiments using his-ubiquitin plasmids and MG132 showed that STK16 overexpression reduced the polyubiquitination level of c-MYC, suggesting that STK16 mediates c-MYC upregulation via the ubiquitin-proteasome pathway (Fig. 4D). Consistent results were observed in loss-of-function experiments (Fig. 4E-F). We also assessed the degradation rate of c-MYC using cycloheximide (CHX) to inhibit protein synthesis. Results showed that STK16 WT, but not STK16 T198A, significantly reduced the degradation rate of c-MYC (Fig. 4G-H). Moreover, IHC assays in colorectal cancer tissues demonstrated a positive correlation between STK16 and c-MYC expression levels (Fig. 4I and Figure S2H). In summary, these results suggest that STK16 activates the MYC signaling pathway by preventing the polyubiquitination of c-MYC.

Fig. 4

STK16 Positively Activated c-MYC Signaling via Stabilizing c-MYC. A. GSEA analysis of TCGA database, patients grouped by the expression level of STK16. B. IB assays assessed the expression of c-MYC signaling-related proteins in cancer cells stably expressing sgCtrl or sgSTK16. C. Treated cancer cells with autophagy-lysosome pathway inhibitor (chloroquine, CQ) or ubiquitin-proteasome pathway inhibitor (MG132), and immunoblotting assays assessed the expression of c-MYC in HEK293T cells. D. Transfected his-ubiquitin plasmid into HEK 293T cells, and IB assays assessed the poly-ubiquitination level of c-MYC in HEK293T cells stably expressing vector or STK16. E, F. Transfected his-ubiquitin plasmid into cells, and IB assays assessed the poly-ubiquitination level of c-MYC in HEK293T or RKO cells stably expressing sgCtrl or sgSTK16. G, H. CHX was applied to inhibit endogenous protein synthesis, and IB assays assessed the degradation rate of c-MYC in HEK293T cells ectopically expressing vector, STK16 WT, or STK16 T198A. I. 63 colorectal cancer samples were collected from People’s Hospital of Xinjiang Uygur Autonomous Region. Statistical analysis of the correlation between the expression level of STK16 and the expression level of c-MYC. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis used Student’s t-test

STK16 stabilized c-MYC by phosphorylating c-MYC at serine 452

We demonstrated that STK16 post-translationally regulates c-MYC expression, and the kinase activity of STK16 is crucial for this process. Consequently, we hypothesized that STK16 might phosphorylate c-MYC. To test this hypothesis, we initially conducted co-immunoprecipitation assays to examine the binding between STK16 and c-MYC. Significantly, we observed binding between STK16 and c-MYC in RKO and Lovo cells (Fig. 5A and Figure S3A). We then used a pan-serine/threonine phosphorylation antibody to assess the phosphorylation level of c-MYC in various cancer cells. Results showed that the gain of STK16, but not STK16 T198A, upregulated the phosphorylation level of c-MYC (Fig. 5B and Figure S3B). Conversely, both loss of STK16 and the pharmacological inhibitor (STK16-IN-1) significantly decreased the phosphorylation level of c-MYC (Fig. 5C and Figure S3C). Next, we sought to identify the serine/threonine site on c-MYC that could be phosphorylated by STK16. Co-immunoprecipitation assays using c-MYC deletion mutants revealed that the deletion of amino acids 422–454 abolished the interaction between c-MYC and STK16 (Fig. 5D). Further experiments with additional c-MYC deletion mutants narrowed down the binding region to amino acids 422–454, specifically amino acids 422 − 421 (Fig. 5E). Sequence analysis indicated two serine sites (S430 and S452) within the 422–454 amino acid region of c-MYC. Mutant plasmids were constructed for these serine sites (S430A and S452A, phospho-deficient mutants). Co-transfection experiments demonstrated that STK16 overexpression increased the phosphorylation level of c-MYC S430A mutant but not c-MYC S452A mutant (Fig. 5F). These results established that STK16 phosphorylates c-MYC at serine 452. Subsequently, we generated RKO and Lovo cells ectopically expressing c-MYC WT, c-MYC S452A, or c-MYC S452E (phospho-mimetic mutants) using the Crispr-Cas9 system (Figure S3D). Immunoprecipitation assays showed that the c-MYC S452A mutant had a higher polyubiquitin level than c-MYC WT, while the c-MYC S452E mutant had a lower polyubiquitin level than c-MYC WT (Fig. 5G). Consistently, cells expressing c-MYC S452A had lower expression levels of GLUT1 and CDK4 compared to cells expressing c-MYC WT, whereas cells expressing c-MYC S452E had higher expression levels of GLUT1 and CDK4 compared to cells expressing c-MYC WT (Fig. 5H). Furthermore, proliferation assays indicated that cells expressing c-MYC S452A had lower proliferation ability than cells expressing c-MYC WT, while cells expressing c-MYC S452E had higher proliferation ability than cells expressing c-MYC WT (Fig. 5I-K). Overall, these findings demonstrate that STK16 phosphorylates c-MYC at serine 452, and c-MYC S452 phosphorylation is essential for its stability.

Fig. 5

STK16 Phosphorylated c-MYC at Serine 452. A. IB and immunoprecipitation (IP) assays confirmed the binding of STK16 and c-MYC. B. IB and IP assays assessed the phosphorylation level of c-MYC in RKO cells stably expressing vector, STK16 WT, or STK16 H198A. C. IB and IP assays assessed the phosphorylation level of c-MYC in RKO cells stably expressing sgCtrl or sgSTK16. D, E. IB and IP assays investigated the binding domain of STK16 and c-MYC. F. Transfected c-MYC S430A or c-MYC S452A mutant plasmid into HEK293T cells, and IB and IP assays assessed the phosphorylation level of c-MYC in HEK293T cells stably expressing vector or STK16. G. IB and IP assays assessed the poly-ubiquitination level of c-MYC WT, c-MYC S452A, or c-MYC S452E. H. IB assays assessed the expression of c-MYC signaling-related proteins in cancer cells stably expressing c-MYC WT, c-MYC S452A, or c-MYC S452E. I-K. CCK8 (I) and Brdu (J, K) assays assessed the proliferation ability of cancer cells stably expressing c-MYC WT, c-MYC S452A, or c-MYC S452E. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis used Student’s t-test

STK16-mediated cancer cell proliferation relied on c-MYC S452 phosphorylation

To further investigate the relationship between STK16 and c-MYC, we generated four types of colorectal cancer cells stably expressing vector + shnc, STK16 + shnc, STK16 + shc-MYC#1, STK16 + shc-MYC#2 using lentivirus. Western blot results demonstrated that STK16 overexpression upregulated the expression of GLUT1 and CDK4, an effect abrogated by c-MYC silencing (Fig. 6A). Next, we assessed the proliferation ability of these four types of cancer cells through CCK8 and BrdU assays. The results indicated that the gain of STK16 enhanced the proliferation ability of cancer cells, while c-MYC silencing counteracted this effect (Fig. 6B-D). Furthermore, we generated four types of colorectal cancer cells stably expressing vector + c-MYC WT, STK16 + c-MYC WT, vector + c-MYC S452A, and STK16 + c-MYC S452A using lentivirus and the Crispr-Cas9 system. Downstream gene expression levels of the c-MYC signaling pathway in these cells were assessed by western blot. Results showed that STK16 overexpression upregulated the expression levels of c-MYC, GLUT1, and CDK4 in c-MYC WT cancer cells, but not in c-MYC S452A cancer cells (Fig. 6E). Consistently, STK16 overexpression enhanced the proliferation ability of cancer cells in c-MYC WT cancer cells, but not in c-MYC S452A cancer cells (Fig. 6F-H). These findings confirm that c-MYC S452 phosphorylation is essential for STK16-mediated cancer cell proliferation.

Fig. 6

c-MYC S452 Phosphorylation Was Essential for STK16-Mediated Cancer Cell Proliferation. A. IB assays detected the expression level of identified proteins in colorectal cancer cells stably expressing vector + shnc, STK16 + shnc, STK16 + shc-MYC#1, or STK16 + shc-MYC#2. B-D. CCK8 (B) and Brdu assays (C, D) assessed the proliferation ability of identified cancer cells. E. IB assays detected the expression level of identified proteins in colorectal cancer cells stably expressing vector + c-MYC WT, STK16 + c-MYC WT, vector + c-MYC S452A, or STK16 + c-MYC S452A. F-H. CCK8 (F) and Brdu assays (G, H) assessed the proliferation ability of identified cancer cells. All IB assays were conducted three times, and consistent results were obtained. Statistical analysis used Student’s t-test

Targeting STK16 was an effective therapeutic strategy for colorectal cancer treatment

Based on the above findings, we investigated whether STK16 could be an effective therapeutic target for colorectal cancer. To test our hypothesis, we conducted animal experiments using Lovo cancer cells stably expressing sgcontrol, sgSTK16#1, and sgSTK16#2. Tumor long and short diameters were measured at indicated times, and after 16 days, mice were sacrificed, and tumors were separated, weighed, and imaged. The results demonstrated that loss of STK16 significantly inhibited the growth rate of cancer cells (Fig. 7A-C). Additionally, overall survival time was recorded for the three groups of mice, revealing that STK16 knock-out noticeably prolonged the overall survival time (Fig. 7D). Immunohistochemistry and western blot assays were performed to assess the expression levels of c-MYC and Ki-67 (representing the proliferation ability of cancer cells), showing that loss of STK16 significantly restrained the expression levels of c-MYC and Ki-67 in vivo (Fig. 7E-F). However, achieving STK16 knockout in clinical treatment in vivo is challenging. Therefore, a pharmacological inhibitor might be an effective and achievable approach for clinical application. Subsequently, we applied the STK16 inhibitor (STK16-IN-1) in xenograft experiments. The results indicated that STK16-IN-1 application not only significantly inhibited the growth and weight of the tumor but also prolonged the overall survival time of mice (Fig. 7G-J). Consistently, results from immunohistochemistry and western blot assays revealed that STK16-IN-1 significantly decreased the expression levels of c-MYC and Ki-67 (Fig. 7K-L). In conclusion, our findings suggest that pharmacologically inhibiting STK16 might be an effective therapeutic approach for colorectal cancer.

Fig. 7

Targeting STK16 Inhibited Colorectal Cancer Proliferation In Vivo. A. Representative tumor images shown. B. Drawing tumor growth curve of the three groups (n = 5). C. Statistical analysis of tumor weight. D. Kaplan-Meier Plot was drawn for the three groups (n = 12). E, F. IHC (E) and IB (F) assays to detect the expression level of identified proteins. G. Representative tumor images shown. H. Drawing tumor growth curve of the two groups (n = 5). I. Statistical analysis of tumor weight. J. Kaplan-Meier Plot was drawn for the two groups (n = 13 for DMSO and n = 12 for STK16-IN-1). K, L. IHC (K) and IB (L) assays to detect the expression level of identified proteins. M. The working model: STK16 inhibits the ubiquitin-proteasome pathway degradation of c-MYC by phosphorylating c-MYC at S452, contributing to colorectal cancer progress