STXBP4 and patient survival
To verify its potential as therapeutic target, STXBP4 was first subjected to a comparative analysis of its clinical prognostic impact with other 6 robust targets and/or potent biomarkers used in current drug therapies: TP63 (representing ΔNp63; TP63), p53 (TP53), VEGFR2 (KDR), TUBB3 (TUBB3), STMN1 (STMN1) and PD-L1 (CD274).
A large-scale public database, The Cancer Genome Atlas (TCGA), was used to obtain data sets, for both gene expression and survival outcome, in 474 primary LSCC patients. Kaplan-Meier analysis of OS and relapse-free survival (RFS) using these data showed that TUBB3 expression alone was correlated with RFS when patients were tentatively classified into positive- and negative-expression groups according to the expression level in each tumor (cut off set as the median, p=0.001) [An additional file shows this in more details (See Additional file 3)]. Despite the lack of statistical significance, the analysis also suggested some prognostic impact of 6 molecules except TP53; i.e., TP63 (p=0.072), TUBB3 (p=0.091), and STMN1 (p=0.052) in OS, and STXBP4 (p=0.076), KDR (VEGFR2, p=0.071), STMN1 (p=0.089) and CD274 (PD-L1, p=0.065) in RFS.
As a single layer of "omics" can only provide limited insights into biological significance, we performed immuno-histochemical analysis to elucidate the relevance of these 7 exploratory targets to patient outcome (Figure 1). A total of 144 patients were enrolled in this study (Table 1). None of the patients received any cancer treatment before the operation and the majority of patients were former or current smokers (97.9%).
The numbers of patients evaluated as demonstrating positive expression were 98 (68.1%) for STXBP4, 91 (63.1%) for ΔNp63 (TP63), 73 (50.7%) for p53, 94 (65.3%) for VEGFR2 (KDR), 53 (36.8%) for TUBB3, 87 (60.4%) for STMN1, and 68 (47.2%) for PD-L1 (CD274) [An additional file shows this in more details (See Additional file 4)]. Positivity of STXBP4 expression was not correlated with any typical clinicopathological factors including pathological stage, but closely correlated with those of ΔNp63 (p=0.008) and VEGFR2 (p=0.024) (See Additional file 5).
Kaplan–Meier analysis of OS and DFS (disease free-survival) revealed that positive STXBP4 expression signified a worse prognosis for LSCC patients, both in terms of OS (p=0.002) and DFS (p=0.041) (Figure 2). Likewise, the positive expression of VEGFR2 was found to be closely connected with shorter OS (p<0.001) and DFS (p=0.007). The close relationship with OS was observed also for ΔNp63 (p=0.013), but any other correlations with patient outcomes, both OS and DFS, were not observed for the other targets examined.
Univariate Cox regression analysis using 13 variables including 6 clinicopathological factors confirmed these observed prognostic impacts of STXBP4 (OS, p=0.0021; DFS, p=0.0405), TP63 (ΔNp63: OS, p=0.0134) and VEGFR2 (OS, p<0.001), along with several clinicopathological parameters, such as pathological stage (I/II-III) (OS, p=0.0232; DFS, p=0.0004), pathological T (OS, p=0.0134), and lymphatic permeation (OS, p=0.0267; DFS, p=0.0001). Multivariate analyses revealed that the positive expression of VEGFR2 (OS, p<0.0001; DFS, p=0.0059) and ΔNp63 (OS, p=0.0324) were independent prognostic factors for poor patient survival, together with pathological stage (DFS, p=0.00096), pathologic T (OS, p=0.0065) and lymphatic permeation (DFS, p=0.0098), but STXBP4 was not (Table 2) .
STXBP4 as a possible therapeutic target
The observed close relationships between VEGFR2, TUBB3, and STMN1 to patient outcome suggested the existence of some biological interactions between STXBP4 and these molecules. Ingenuity pathway analysis (IPA) using the knowledge database demonstrated that STXBP4 acts as an up-stream regulator of TP63 (ΔNp63) and subsequently of KDR (VEGFR2) via TP63, but the action pathway of STXBP4 was independent from those of the other 4 exploratory targets (Figure 3A, B).
To confirm this, we performed in vitro experiments using human LSCC cell lines. According to the half-maximal inhibitory concentration (IC50) published on the Genomics of Drug Sensitivity in Cancer (GDSC) database (https://www.cancerrxgene.org), we first chose 4 cell lines (LK-2, EBC-1, NCI-H520, and RERF-LC-AI), and then selected 2 cell lines as totally drug-sensitive (LK-2) and -resistant cells (RERF-LC-AI). The selection was based on a CCK8 assay to confirm the cellular sensitivities to cisplatin (CDDP), 5-fluorouracil (5-FU), and docetaxel (TXT) shown on GDSC database, and newly examine their sensitivities to Ramucirumab (IC25); however, their cellular sensitivities to immune-check point inhibitors could not be studied using the same cytotoxic assay [An additional file shows this in more details (See Additional file 6)]. Despite the limited data, correlative analysis of drug sensitivity and gene expression (ArrayExpress, https://www.ebi.ac.uk/arrayexpress//experiments/E-MTAB-2706/) in 4 cell lines suggested that TP63 expression was related to cellular sensitivity to CDDP [An additional file shows this in more details (See Additional file 7)].
Exposure of cells to a drug causes a dynamic alteration in gene expression, and RNA-seq analysis following such drug treatment enables us to identify all the genes modulated together in response to the drug. VEGFR2 and TUBB3 are the drug action targets of Ramucirumab and TXT, respectively, and STMN1 has been suggested to be a marker of tumor resistance to taxanes (14-17). LK-2 and RERF-LC-AI cells were treated with or without TXT and Ramucirumab in single and combination treatment settings, and then subjected to RNA-seq analysis. We selected genes highly correlated in terms of expression level with each target gene, and then performed hierarchical clustering of canonical pathways.
The analysis showed that STXBP4, TP63 and KDR (VEGFR2) formed a cluster independent from the other target genes [TP53, TUBB3, STMN1 and CD274 (PD-L1)], which was in accord with the findings obtained in our previous studies (Figure 4) [An additional file shows this in more details (See Additional file 8)] (10). Thirty-five pathways were extracted as significantly (|activation z-score| >=2) activated or inactivated pathways in correlation with STXBP4. Among them, the EIF2 signaling pathway, which plays a critical role in stress-related signals to regulate both global and specific mRNA translation, was the most significantly activated [An additional file shows this in more details (See Additional file 9)].
The action pathway of STXBP4 is distinct from those of other conventional drugs such as TXT and immuno-checkpoint inhibitors. The pathway is thought to suppress 2 prominent determinants of poor prognosis in LSCC patients, TP63 and VEGFR2, and possibly p53 as well.
STXBP4 as a possible predictive biomarker of individual therapeutic response
The observed correlations between STXBP4, ΔNp63, and VEGFR2 and clinical outcome, particularly the close correlation between STXBP4 and DFS, suggested that STXBP4 expression might afford a powerful predictive biomarker of individual response to current therapy. This hypothesis, however, cannot be directly verified due to the insufficient number of available coupled data related to clinical response and omics profiling, even when a large-scale public clinical and genomic database was used.
Our in vitro experiments clarified the relevance of each exploratory target to drug response at least in part. RNA-seq analysis revealed that CD274 (PD-L1) expression alone was significantly higher in the totally drug-resistant RERF-LC-AI cells as the base line [An additional table file shows this in more details (See Additional file 6)]. In the drug sensitive LK-2 cells, none of the drug treatments caused any significant changes in the expression levels of the 7 targets examined (Table 3). In the resistant RERF-LC-AI cells, however, all of the drug treatments, single TXT, single Ramucirumab, and their combination, yielded a significant up-regulation in TP63 (representing ΔNp63) and a remarkable down-regulation in CD274. Ramucirumab also significantly increased STMN1 expression in the resistant cells. No changes in the expression levels of STXBP4, KDR (VEGFR2), or TUBB3 were observed, regardless of the cell lines and drug treatments examined.
These findings suggested that the high-level expression of CD274 (PD-L1) is related to cellular drug resistance, at least in part, but could be partially down-regulated by TXT and/or Ramucirumab. TP63 (ΔNp63) induction might be involved in the cellular resistance mechanisms of LSCC to TXT and/or Ramucirumab treatment, and the up-regulation of STMN1 could also participate in Ramucirumab resistance. These findings may afford some help in the development of precision medicine for LSCC patients, with the optimal treatment for individual LSCC patients selected through expression analysis of CD274, TP63, and STMN1. STXBP4 is a potent prognostic marker in LSCC patients but not a powerful predictive marker of individual response to widely used current therapeutic drugs.