Abstract
The chromosome 20 long arm (20q) is one of the genomic hotspots where copy number alterations frequently occur in multiple types of tumors. However, it remains elusive which genes are implicated in 20q-related tumorigenesis. Here, by querying TCGA and GEO databases, we observed frequent copy number amplification at 20q and the chromosome subband 20q13.33 was amplificated in multiple cancers. Among those genes at 20q13.33, PSMA7 was found with the strongest correlation with cancers. Further analysis revealed that PSMA7 amplification was the most frequent genetic alteration event conferring adverse prognosis in various cancers. Consistent with the strong positive correlation between PSMA7 amplification and gene expression, elevated PSMA7 expression was observed in 20 of 33 types of cancers with a close link to adverse outcomes in certain tumors. In addition, PSMA7 was essential for the growth of almost 1095 cancer lines. Mechanistically, aberrant PSMA7 most probably influenced the proteasome and protease-related pathways to promote tumorigenesis and might be antagonized by several compounds, e.g., Docetaxel in relevant cancers. The current in-depth pan-cancer analysis refines our understanding of the crucial oncogenic role of copy number amplifications at PSMA7 loci at the novel chromosome amplicon 20q13.33 across different tumors.
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Introduction
Copy number alterations (CNAs) are one of the types of genomic alterations that additionally consist of mutation (single nucleotide variation), chromosomal inversion, and translocation among others1. CNAs include amplifications (more copies, often focal), gains (a few additional copies, often broad), and deep and shallow deletions/losses (homozygous and heterozygous deletions)2. CNAs can impair genomic stability and dysregulate the involved genes to exert pro- or anti-tumor effects2. Previous scattered studies revealed the chromosome 20 long arm (20q) as one of the CNA hotspots harboring various cancer-related genes3. The 20q was frequently deleted or lost in hematological neoplasms4, while in ovarian cancer, upregulated genes and relevant aberrant DNA amplification were commonly concentrated at 20q5. Moreover, abnormal amplification of 20q was commonly reported in Barrett adenocarcinoma (BA+) tumor6 and colorectal7, breast8, prostate9, pancreatic10, and bladder11 cancers. Notably, Murty et al.12 found 20q11.2 and 20q13.13 as the novel chromosomal amplification loci carrying tumor-related genes in cervical cancer. Although these findings suggested critical roles of amplification at 20q in various tumors, it remained unclear which genes played a predominant role at 20q.
The proteasome subunit alpha-type 7 (PSMA7) encodes the alpha-type subunit of the 20S proteasome core complex from the 26S proteasome of the ubiquitin–proteasome system (UPS). By forming a regulatory structure “gateway” with other proteasome subunits, PSMA7 can modulate protein degradation13. Moreover, PSMA7 interacts with multiple important proteins including c-ABL14, hypoxia-inducible factor-1α (HIF-1α)15, hepatitis B virus (HBV) X (HBX) protein16, Rab717, and endothelial monocyte-activating polypeptide 2 (EMAP2)18. Thanks to these interactions, PSMA7 is implicated in diverse cancer-related cellular activities, including transcription control, immunologic reaction, stress responses, cell cycle regulation, cellular differentiation, proliferation, and apoptosis. Additionally, c-ABL-mediated upregulation of PSMA7 led to the formation of alternative proteasome isoforms of PSMA7-PSMA7, eventually influencing cancer cell fitness19,20.
PSMA7 overexpression has been observed in gastric21,22, cervical12,23, and testicular24 cancers and is shown to be closely linked to metastasis25, progression26, and reduced life span27,28 in certain cancers. Mechanistically, deficiency of PSMA7 could inhibit cellular proliferation, migration, and invasion in colorectal29, gastric22, and breast30 cancers, and high-grade serous ovarian carcinoma (HGSOC)31. Besides, PSMA7 depletion blunted the G0/G1 cell cycle and led to apoptosis of cervical cancer cells23. It was evidenced that the PSMA7-mediated proteasome degradation was essential to maintain cell survival of HGSOC31, cervical23, and castration-recurrent prostate cells32. Additionally, PSMA7 was found to contribute to tumorigenesis by activating the nuclear factor-κ-gene binding (NF-κB) pathway33 and the mitogen-activated protein kinase (MAPK) signaling pathway22, and interactions with miRNAs30. All these discoveries point to an oncogenic role of PSMA7 in certain tumors. However, the precise roles and relevant mechanisms of PSMA7 across human cancers remained less well understood.
Hereby, combining the cancer genome atlas (TCGA) and gene expression omnibus (GEO) data, we carried out a pan-cancer exploration of PSMA7 at 20q concerning genetic alteration, survival state, gene expression, cellular pathway, molecular function, and potential drug screening, aiming to uncover the mechanisms of PSMA7 in tumorigenesis and clinical outcomes across diverse human cancers.
Results
The amplification of chromosome 20q at the pan-cancer level
To depict the genomic landscape of chr20 in human tumors, we employed the revised Genomic Identification of Significant Targets in Cancer (GISTIC2.0) pipeline34,35,36 to integrate the copy number raw data from 33 types of TCGA tumors (Fig. 1A, B, Supplementary Tabs. S1–S3). Overall, the statistical data for each chromosome arm revealed that the broad genomic amplification was more significant in the 20q than in the short arm of chr20 (20p) at the pan-cancer level (Fig. 1A, Supplementary Tab. S1). Consistently, this discovery was confirmed when the online SNP6 copy number analysis (GISTIC2) from Broad Firehose35 was run by each type of TCGA cancers in turn (Supplementary Fig. S1A). Besides, the GISTIC2.0-based pan-cancer integrated analysis detected only 3 focal events (amplification: 2; deletion: 1) located at chr20 (Fig. 1B, Supplementary Tabs. S2, S3), suggesting that amplification at chr20 was mostly in a broad level.
After downloading the data for CNA genes from the cBioPortal37,38, we queried the median frequency of amplification of mapped genes in tumor samples and further illustrated the amplification frequency in the corresponding chr20 subband (Table 1). Excluding chromosome subbands with less than 10 genes, the overall amplification frequency of 20q was 2.25%, which was significantly higher than that of 20p (0.8%). This finding highlighted the predominance of amplification in 20q (Fig. 1A, Supplementary Fig. S1A). Notably, 20q13.33, which involves 85 genes, displayed the highest alteration frequency of 2.7%, highlighting this region as a novel chromosome amplicon. Although amplification at this region was identified as a broad CNA event by pan-cancer integrated copy number analysis (Fig. 1B, Supplementary Tabs. S2, S3), the focal amplification of 20q13.33 was further found in 7 (of 30) tumor types of liver hepatocellular carcinoma (LIHC), lung adenocarcinoma (LUAD), ovarian serous cystadenocarcinoma (OV), rectum adenocarcinoma (READ), sarcoma (SARC), skin cutaneous melanoma (SKCM), and uterine corpus endometrial carcinoma (UCEC), according to detailed amplification plots generated by the online tool GISTIC2 from Broad Firehose (Supplementary Fig. S1B). Other relatively frequent chromosome subbands included 20q13.32, 20q13.2, and 20q13.31, with an amplification frequency of 2.6%, 2.6%, and 2.5%, respectively. 20q13.13 was another candidate amplicon with a relatively higher amplification frequency of 2.3% (Table 1), which had been identified in cervical cancer previously12. These findings revealed that amplification was a quite common genetic event for 20q, and 20q13.33 was likely to be an uncharted amplicon in human cancers.
To investigate which pathways were mainly involved in the 20q13.33-amplified cancers, we conducted an enrichment analysis of the 85 genes at 20q13.33 (Fig. 1C, D). The Kyoto Encyclopedia of Genes and Genomes (KEGG) and gene ontology (GO) data manifested that most genes were significantly enriched in multiple cancer-related cellular and molecular functions, especially of translocations between the nucleus, nucleoplasm, and chromatin, cell proliferation, and differentiation (Fig. 1D). However, it remained undetermined which gene primarily mediated the effects of amplified 20q13.33 on cancer initiation and development. Thus, we used the Phenolyzer39 tool to evaluate the potential association of the 85 genes at 20q13.33 with cancer development. Notably, PSMA7, one of the proteasome family members, achieved the highest correlation score of 0.452 with cancer (Fig. 1E), suggesting the crucial oncogenic role of PSMA7 in 20q13.33. We thus focused on PSMA7 for further study.
PSMA7 gene amplification occurs in multiple types of tumors.
To comprehensively explore the genetic alterations of the PSMA7 gene locus rather than CNA1,2, we conducted a genetic alteration survey of PSMA7 across 32 types of TCGA cancers via the cBioPortal approach. The genetic alterations of PSMA7 were found in a total of 25 types of tumors, and amplification was the most frequent molecular alteration observed in PSMA7 (Fig. 2A). The uterine carcinosarcoma (UCS) cases carried the utmost amplification incidence of PSMA7 (~ 8.8%), followed by colon adenocarcinoma (COAD) (~ 6.7%) and OV (~ 6.2%). Finally, we discovered that cohorts with thymoma (THYM) harbored deep deletion of PSMA7 with the highest frequency (0.81%) but represented a minority of cancers.
Consistent with the above results, according to the Gene Set Cancer Analysis (GSCA) (a TCGA-based tool)40, the CNA of PSMA7 was the major genetic alteration event observed in 33 types of TCGA tumors (Fig. 2B). The highest CNA frequency appeared in nearly 95% of patients with READ. In addition, the amplified CNA of PSMA7 predominated in each type of tumor with a frequency of up to 80%, while the copy number deletion was most frequently observed in less than 15% of patients with lung squamous cell carcinoma (LUSC). Furthermore, both amplification and deletion of CNA occurred in heterozygous status, with the highest frequency of 80% in cases with READ (Fig. 2C). In contrast, the homozygous CNA was most commonly observed in only 21% of patients with UCS (Fig. 2C). These data indicated that heterozygous copy number amplification of PSMA7 represented the major genetic variation event across the TCGA tumors.
PSMA7 amplification exhibits a positive link to gene expression
Emerging evidence supported that genomic alterations could alter the transcript levels of mapped genes to promote cancer development and progression2. Thus, we asked whether copy number amplification of PSMA7 affected its gene expression levels. Based on the GISTIC database, the PSMA7 expression level in the amplification of putative CNA was significantly higher than that in other types of CNA (Fig. 2D). Besides, spearman correlation analysis via the GSCA web also documented that the PSMA7 CNA exhibited a positive link to gene expression in 23 of 33 types of TCGA tumors with false discovery rate (FDR) ≤ 0.05 (Fig. 2E). The correlations in detailed cancers were displayed inSupplementary Fig. S2, especially 0.8 in READ and 0.78 in COAD. Collectively, these data suggested that copy number amplification of PSMA7 might lead to gene overexpression in human cancers.
Differentially expressed PSMA7 between cancer and normal tissues
Having confirmed a close positive association of copy number amplification of PSMA7 with gene expression (Fig. 2D, E, Supplementary Fig. S2), we further verified whether PSMA7 was overexpressed in diverse TCGA cancers, contrasting with healthy volunteer samples via the tumor immune estimation resource 2 (TIMER2)41. In doing so, elevated PSMA7 expression was confirmed in the cancers of bladder urothelial carcinoma (BLCA), breast invasive carcinoma (BRCA), cholangiocarcinoma (CHOL), COAD, esophageal carcinoma (ESCA), glioblastoma multiforme (GBM), head and neck squamous cell carcinoma (HNSC), LIHC, LUAD, LUSC, READ, stomach adenocarcinoma (STAD), UCEC, and cervical squamous cell carcinoma and endocervical adenocarcinoma (CESC), prostate adenocarcinoma (PRAD), thyroid carcinoma (THCA), as compared with the matched control tissues (Fig. 3A).
Furthermore, adding the healthy samples of the genotype-tissue expression (GTEx) dataset to the current control group, we observed significantly overexpressed PSMA7 in tumor samples of diffuse large B-cell lymphoma (DLBC), GBM, pancreatic adenocarcinoma (PAAD), and THYM (Fig. 3B), but not in other tumors, including adrenocortical carcinoma (ACC), CESC, brain lower-grade glioma (LGG), OV, SKCM, testicular germ cell tumors (TGCT), or UCS (Supplementary Fig. S3A) by the gene expression profiling interactive analysis 2 (GEPIA2)42. Moreover, PSMA7 expression showed significant differences across the pathological stages of BRCA and LIHC while not including other tumors (Fig. 3C, Supplementary Fig. S3B). Taken together, these data showed that PSMA7 overexpression frequently occurred in most human cancers.
PSMA7 amplification is an adverse prognostic factor in most tumors.
The prognostic significance of PSMA7 CNAs (amplification, deletion, and wild type) was evaluated by log-rank survival analysis using the TCGA dataset (Fig. 4A, Supplementary Fig. S4). The kidney renal clear cell carcinoma (KIRC) patients harboring CNA amplification achieved shorter progression-free survival (PFS) and disease-specific survival (DSS) than those without CNA. Similarly, a reduced median time of DSS was observed in patients with THCA and uveal melanoma (UVM) with amplification. Nevertheless, the highly amplified CNA of PSMA7 was linked to better PFS and disease-free interval (DFI) for ACC. In contrast, the amplified CNA of PSMA7 was associated with worse PFS, DSS, DFI, and overall survival (OS) prognosis for UCEC. Patients with LGG with amplification had a shorter median time of OS, PFS, and DSS, and those with SARC with amplified CNA suffered much shorter OS and PFS times when compared with cases without variations. The amplified CNA of PSMA7 was related to worse DFI for BLCA and lymphoid neoplasm DLBC, but similar OS for CESC. The above results showed that copy number amplification of PSMA7 was a predominant genetic alteration event with adverse outcome effects on most TCGA tumors.
To evaluate whether the amplification of PSMA7 represented an independent prognostic factor in the above tumors, we introduced a multivariate Cox regression model to adjust for established clinical variables such as patient age, tumor stage, and histological grade (Supplementary Tabs. S4-S8). Using survival data from Genomic Data Commons43, we found that amplification of PSMA7 achieved a relatively higher hazard ratio (HR) with all P values below 0.01 in OS, progression-free interval (PFI), and DSS of LGG, respectively, compared to diploid. However, this statistical trend remained significant merely for OS of LGG after isocitrate dehydrogenase (IDH) mutation and 1p/19q co-deletion were enrolled. Similarly, the amplified PSMA7 exhibited significant HRs exceeding 1 for OS and DSS in patients with SARC, contrasting to those with normal diploids. Notably, the OS of THCA showed the highest HR of 44.04 for amplified PSMA7 with statistical significance when patient age was a continuous variable. In addition, we also observed an HR below 1 with a P value less than 0.05 for amplification of PSMA7 in PFI of KIRC, but no positive data for common survival indicators of UCEC, BLCA, and ACC (data not shown). These findings further suggested that amplification of PSMA7 might be an independent adverse biomarker for survival in certain types of tumors.
The overexpressed PSMA7 is linked to adverse clinical outcomes in tumor patients
Next, we employed GEPIA2 to investigate the prognostic significance of PSMA7 overexpression across numerous cancers according to the TCGA and GEO projects. The overexpressed PSMA7 displayed a considerable link to the bad OS of ACC, BLCA, HNSC, LGG, LIHC, and UVM in the TCGA cohorts (Fig. 4B). Additionally, elevated PSMA7 expression showed an association with reduced disease-free survival (DFS) in the TCGA samples of ACC, BLCA, LGG, PRAD, and TGCT (Fig. 4C).
Furthermore, the Kaplan–Meier (K-M)44 plotter-based survival analysis was carried out to reveal the influence of high PSMA7 expression on the clinical prognosis of breast, ovarian, lung, gastric, and liver cancers (Supplementary Fig. S5A–E). As expected, breast cancer patients with elevated PSMA7 expression exhibited poor OS, relapse-free survival (RFS), and DFS. Similarly, overexpressed PSMA7 showed a connection with adverse OS but not PFS or post-progression survival (PPS) for ovarian cancer, whereas poor OS and PPS but good first progression (FP) for lung carcinoma. In gastric cancer, elevated PSMA7 expression merely exhibited a significant link with inferior FP. Moreover, the upregulated transcript level of PSMA7 had a close link to poor OS and RFS while not PFS or DFS for liver cancer. The meta-analysis of these survival data further confirmed that PSMA7 overexpression was an adverse factor for breast, gastric, and liver cancers but not ovarian or lung cancers (Supplementary Fig. S6). Additionally, consistent results were shown in survival analyses by subgroup when detailed clinical factors were considered (Supplementary Tabs. S9–S13). These aforementioned discoveries suggested that highly expressed PSMA7 represented a poor prognostic biomarker for most human tumors.
Abnormal PSMA7 adversely influences genomic DNA stability
As an initiating step of tumorigenesis, genomic instability (GIN) can induce various cancer-related pathological processes such as DNA damage reaction defects, cell cycle checkpoint dysfunction, and oncogene activation45. The GIN can be measured by two biological indicators, microsatellite instability (MSI)46 and tumor mutational burden (TMB)47. In particular, the TMB has become a reliable biomarker to predict the response to programmed death 1 and ligand 1 (PD-1/PD-L1) therapy for cancers47. In this regard, we attempted to explore the possible link of PSMA7 expression to TMB and MSI across TCGA tumors. Consistent with the expected result, PSMA7 expression exhibited a positive relationship with MSI of KIRC, DLBC, TGCT, kidney renal papillary cell carcinoma (KIRP), LIHC, UCEC, and BLCA (Supplementary Fig. S7A), pointing to compromised DNA mismatch repair function in these tumors. Besides, PSMA7 expression also harbored a positive association with TMB in most types of tumors, including SARC, PAAD, BRCA, LGG, LUAD, STAD, SKCM, ACC, OV, LIHC, LUSC, PRAD, and BLCA (Supplementary Fig. S7B). Collectively, we postulated that aberrant high expression of PSMA7 might result in decreased genomic stability in a general way and serve as a predictive immunotherapy biomarker.
Next, we wondered why PSMA7 alterations imposed such a great negative influence on genomic stability. Since amplification of PSMA7 accounted for predomination in genetic alteration types, we compared the alteration frequency of genes in 276 cases with CNA-amplified PSMA7 and that in 10,684 cases without the corresponding PSMA7 abnormality in TCGA tumors (Supplementary Fig. S8A). Interestingly, among 373 differential genes with an alteration frequency over a 5.5 log ratio, 122 (32.71%) genes preferentially were centralized at chromosome 20 (Supplementary Fig. S8B). Further analysis revealed that 84 of 122 (68.25%) genes were mostly enriched in the region of chromosome 20q13.33 where PSMA7 was exactly located (Supplementary Fig. S8C). The top 30 genes ranked by the frequency at 20q13.33 were visually displayed in Supplementary Fig. S8D. In contrast to genes in samples without amplified PSMA7, most of those in cases with PSMA7 amplification experienced high alteration burdens, with frequencies of nearly 80%. These discoveries suggested again that 20q13.33 harboring PSMA7 among others was plausibly a novel amplicon that frequently existed in human cancers. In addition to 20q13.33, we also found other chromosomal amplification sites, such as 20q13.32, 20q13.31, and 20q13.2 (Supplementary Fig. S8B), corresponding to the potential chr20 amplicons ranked by amplification frequency in Table 1. The results manifested a co-occurrence amplification pattern of PSMA7 and other 20q-related genes that together contributed to GIN.
The underlying molecular mechanism of aberrant PSMA7 in tumorigenesis
Given that the aberrant PSMA7 expression possibly adversely influenced the clinical outcome of various cancers (Fig. 4B, C, Supplementary Fig. S5A–E), we then explored the possible molecular mechanism linking high expression of PSMA7 to tumorigenesis. With this regard, the dependency of tumor cells on PSMA7 was evaluated by the genome-scale CRISPR-Cas9 knockout screens in the 1095 cancer cell lines extracted from the Depmap48 database. The PSMA7 depletion resulted in significantly negative screen scores (concentrate range: − 2.0 to − 3.0) in the majority of types of cancers (Fig. 5A), highlighting that PSMA7 was required for tumor cell growth as previously reported23,31,32.
Furthermore, via the STRING tool, the specific interaction network between 50 PSMA7-binding proteins supported by experimental evidence was visualized in Fig. 5B. In parallel with this, the top 100 genes with strong correlation with PSMA7 expression were generated by the GEPIA2 online tool. Notably, PSMA7 expression was positively correlated with selected 18 genes (all P ≤ 0.001) (details in Fig. 5C). In good accordance with this, validation by TIMER2 revealed the positive link of PSMA7 to each of the aforesaid 18 genes across most TCGA cancers (Fig. 5D). By overlapping the above two groups via the Jvenn49, nine common genes were identified, including ADRM1 (ADRM1 26S Proteasome Ubiquitin Receptor), POMP (Proteasome Maturation Protein) , PSMA2 (Proteasome 20S Subunit Alpha 2), PSMA4 (Proteasome 20S Subunit Alpha 4), PSMA5 (Proteasome 20S Subunit Alpha 5), PSMB1 (Proteasome 20S Subunit Beta 1) , PSMB2 (Proteasome 20S Subunit Beta 2), PSMD7 (Proteasome 26S Subunit, Non-ATPase 7) and PSMD14 (Proteasome 26S Subunit, Non-ATPase 14 ) (Fig. 5E).
Next, we subjected those PSMA7-interacting proteins and genes whose expression harbored connections with PSMA7 to the enrichment analysis. As foreseen, the KEGG-based findings manifested that the proteasome, cell cycle, ubiquitin-mediated proteolysis, and nucleocytoplasmic transport might participate in PSMA7-mediated tumorigenesis (Fig. 5F). Besides, GO data revealed that most genes were concentrated on protease activity-related pathways and cellular processes, especially proteasome binding or complex, threonine-type peptidase and endopeptidase activity, endopeptidase activity or complex, and peptidase complex, to guide the biological processes such as anaphase—promoting complex—dependent catabolism, RNA polymerase II transcriptional regulation, and control of cell cycle progression (Fig. 5G, Supplementary Fig. S9A, B). These results documented that aberrant PSMA7 expression greatly influenced UPS status and thus mediated various downstream biological processes, eventually promoting tumor cell growth.
Candidate PSMA7-resistant and sensitive compounds
Elevated PSMA7 expression was considered a prognostic molecular biomarker that might become a new treated target for different types of tumors. However, previous studies suggested the potential involvement of increased PSMA7 protein levels in drug resistance. To uncover the drug-response landscape of cancers expressing upregulated PSMA7, we analyzed the potential connection of drug sensitivity with this gene mRNA expression across pan-cancers based on the drug sensitivity in cancer (GDSC) and cancer therapeutics response portal (CTRP) databases. Overall, positive correlation (R) values with FDR ≤ 1.0e−5 were obtained in compounds of 89 (of 481) and 18 (of 251) in CTRP and GDSC, respectively, which were considered PSMA7-resistant agents (Fig. 6A). Figure 6B displays the top 30 ranked resistant compounds in each drug library. To further find the candidate most PSMA7-resistant agents, we overlapped the data and identified four shared compounds in both CTRP and GDSC (Fig. 6A, Table 2). Since PSMA7 overexpression was validated due to amplification in clinical samples with different types of cancers, we further asked whether PSMA7 amplification showed poor response to these resistant agents, for instance, the first-ranking compound TPCA-150. As expected, strong positive correlations existed between PSMA7 expression and amplification in cell lines with TPCA-1 treatment based on the data from GDSC and CTRP51 (Fig. 6C). Using the genomic data from the catalogue of somatic mutations in cancer (COSMIC)52 database, we found that COSMIC-annotated PSMA7 copy number gain and overexpression occurred in a total of nine cancer cell lines treated with TPCA-1 in GDSC and CTRP (Supplementary Tab. S14). Besides, almost all of these cell lines had high half maximal inhibitory concentrations (IC50) and poor area-under-the-curve (AUC) sensitivity scores for TPCA-1, suggesting that amplification of PSMA7 might protect cancer cell lines from TPCA-1 treatment. These results manifested that PSMA7-related cancers might not benefit from these potentially resistant agents, which required much more validation in future research.
Although PSMA7-resistant compounds accounted for the majority, we found six compounds with negative R-values and FDR ≤ 0.05 in GDSC that might be sensitive to cancers with elevated PSMA7 expression (Fig. 6A, Table 2). The first-ranking agent was Docetaxel, an efficient microtubule depolymerization inhibitor53 which had been approved to treat multiple types of tumors such as advanced breast cancer54, gastric cancer55, and melanoma56. Consistent with the aforementioned finding, PSMA7 expression in the cell lines treated with Docetaxel was also positively correlated with amplification in both GDSC and CTRP (Fig. 6D). Furthermore, we observed that most of the above nine cell lines with PSMA7 copy number gain and elevated expression achieved low IC50 to Docetaxel treatment (Supplementary Tab. S14), highlighting the promising therapeutic value of this agent for PSMA7-related cancers. The data above generally described the drug-response pattern of abnormal PSMA7 in cancer cell lines that need further exploration in future work.
Discussion
CNA is a common phenomenon regulating target gene expression in a wide variety of cancers1,2. Recent advances manifested that 20q was widely amplified and gained in solid tumors3,12. Most of the 20q CNAs and some potential cancer-driver genes conferred poor prognosis and therapeutic vulnerability by influencing immortalization, genomic instability, apoptosis, and proliferation57. In myeloid hematological malignancies, however, deletion or loss of 20q and the involved common-deletion region (CDR) candidate genes correlated with a relatively good prognosis as a de novo chromosomal event58. These findings emphasized the heterogeneous role of 20q CNAs in human cancers. In this study, we for the first time revealed that 20q13.33 was the most frequently amplified genomic loci at a pan-cancer level. Notably, aberrant high expression of the PSMA7 gene at 20q13.33 due to amplification conferred poor prognosis and therapeutic vulnerability in various cancers12,25. In this regard, by querying GDSC and CTRP databases, we proposed several candidate compounds, holding the promise to develop new therapeutics for relevant cancers.
In the past years, the correlation between elevated PSMA7 expression with adverse prognosis was reported by sporadic research12,21,22,23,24,25,26,27,28. Recently, a TCGA-based pan-cancer study mentioned briefly the prognostic valus of 49 proteasome family member genes including PSMA759, which indeed serves as a significant precursor to our own research. During the explorations of CNA of chr20 using similar genomic data from TCGA tumors, we identified PSMA7 as the most potential target at the newly found amplicon of 20q13.33. Then we at a pan-cancer level systematically explored the status of amplification and expression of the PSMA7 gene and their clinical significances in terms of prognosis and potential therapeutic opportunity. Distinguishing from the previous pan-cancer research focusing on the prognostic values of PSMA7 59, we further investigated the underlying mechanism linking high PSMA7 expression to poor prognosis. Analysis of proteins interacting or genes correlating with PSMA7 revealed broad functions of PSMA7 in multiple cellular processes13, especially networks with proteasome binding or complex. Moreover, we found that PSMA7 was significantly essential for tumor cell viability in the CRISPR-mediated loss of function screens of 1095 cancer cell lines. These findings suggested that the PSMA7-mediated proteasome activity might necessarily support tumor cell survival, as reported previously23,31,32. Moreover, Hochstrasser et al. found that elevated cellular PSMA7 levels increased preferentially the assembly of PSMA7-PSMA7 proteasome alternative isoform and protected tumor cells from the environmental pressure induced by heavy metals20. However, more experiment-based evidence is warranted to prove this hypothesis.
Notably, we discovered that PSMA7 expression displayed a positive link to TMB and MSI in diverse tumors, figuring out the potential role of PSMA7 in DNA damage repair for tumor cells45. According to the two-hit hypothesis of tumorigenesis60, amplification of 20q13.33 might serve as the first “hit”, and aberrant high expression of PSMA7 might contribute to the second “hit” required for overt tumorigenesis by introducing more genetic lesions. Interestingly, PSMA7 can be used as a plausible immunotherapy predictive biomarker, given its correlation with TMB47. Besides, we further identified a cohort of other differentially overexpressed genes between samples with and without PSMA7 amplification, revealing a co-occurrence amplification pattern of PSMA7 and other genes across whole chromosomes, especially 20q. One noteworthy co-amplified gene was LAMA5 located at 20q13.33, a member of the laminin family that encoded the α chain of the extracellular matrix protein laminin 561. This gene was found to promote migrations of some tumors62,63 and thus achieved a comparable score with PSMA7 in cancer in the current study (Fig. 1D). The amplification of LAMA5 which harbored the highest gene expression than any other CNA types was indeed observed in 23 (of 32) types of TCGA tumors in cBioPortal (Supplementary Fig. S10 A, B). However, genome-scale CRISPR-Cas9 knockout screens showed that LAMA5 depletion resulted in nearly zero in almost all types of cancers, suggesting LAMA5 was not required for tumor cell survival (Supplementary Fig. S10C). Therefore, we inferred that the chromosome amplicon 20q13.33 might be the work unit in which PSMA7 but at least not LAMA5 functioned as a cancer-promoting factor. Given its critical role in tumorigenesis, therapeutic compounds targeting the PSMA7 pathway were screened using CTRP and GDSC databases, with six of them showing therapeutic potential. Further validation to test the anti-tumor effects of these candidate compounds will provide more evidence to support this.
Taken together, our study supported PSMA7 as the crucial gene at the 20q amplification hotspot and a potential new biomarker for the diagnostic testing, prognostic evaluation, and molecular therapeutic development of human cancers. Identification of several chromosome 20q amplicons, especially the novel amplicon 20q13.33 consisting of the amplified PSMA7 and other overexpressed genes, presents a more comprehensive landscape of genomic amplification of 20q, and the oncogenic role and underlying molecular mechanism of PSMA7 at a pan-cancer level.
Methods
Genetic variation analysis
The GISTIC2.0 pipeline34,35,36 was applied to analyze the copy-number raw data from 33 types of TCGA tumors and achieve the total segmented copy-number profile and the broad and focal CNA regions across the whole genome. The results were visualized as a heatmap and detailed chromosome frequency plots. The online tool GISTIC2 from Broad Firehose35 was employed to obtain statistical data for each chromosome arm and detailed amplification frequency plots across the whole genome in 30 types of TCGA tumors. The “TCGA Pan Cancer Atlas Studies” of the “Quick select” module of the cBioPortal approach37,38 was operated with “Explore Selected Studies” to download the data for "CNA genes" from the “Summary” module. We summarized the amplification frequency of each chr20 subband and performed a Mann–Whitney U test in which a P value less than 0.05 was considered statistically significant. The enrichment analysis of genes at the chromosome subband with the highest amplification frequency was performed by the KEGG and GO. Additionally, we employed another tool Phenolyzer39 to explore the potential link of genes to cancer.
For PSMA7, the “Cancer Types Summary” section on this web was queried to quickly acquire the genomic variations including frequency, mutation type, and CNAs of this gene in TCGA tumors. The PSMA7 expression level in various types of putative CNA was investigated in the “PLOT” module. Besides, the “Genomic Alterations” module in the “Comparison/Survival” section was employed to get the difference in co-occurrence pattern between other altered genes and amplified PSMA7 in TCGA patients with or without PSMA7 copy number amplification. We focused on the differential genes with statistically significant alteration frequencies above the 5.5 log ratio and observed their chromosomal and subband distributions.
According to the GSCA database40, the “Copy Number Alteration (CNA)” module in the “Mutation” section was employed to reveal the genetic alteration of PSMA7 in TCGA tumors. The CNA frequency, genotype status, and their association with survival prognosis were observed in the “CNA summary”, and “CNA & Survival” modules, respectively. The log-rank and Cox regression tests were each applied for the prognosis estimation of CNA on OS, PFS, DFI, and DSS. The multivariate Cox regression analysis was further performed to evaluate whether the amplification of PSMA7 represented an independent factor by adjusting established clinical and molecular variables. The relationship of PSMA7 CNA with gene expression was evaluated in the “CNA & Expression” module. In addition, the “Pan-Cancer” section of the Assistant for Clinical Bioinformatics web was employed to estimate the possible link of PSMA7 expression to TMB and MSI.
Differentially expressed gene analysis
The PSMA7 expression across TCGA tumors was compared with that in normal samples through the “Gene_DE” section of the TIMER2 online41. Notably, for tumors with rare numbers of normal samples, the adjacent healthy volunteer samples of the GTEx dataset were added. Then PSMA7 expression in those tumors was reevaluated by the “Expression Analysis-Box Plots” section of the GEPIA242. Furthermore, the “Pathological Stage Plot” section was operated with PSMA7 to investigate gene expression at each pathological stage of diverse TCGA cancers. We presented these results in violin plots.
Survival analysis
With the setting of the median expression level of PSMA7 as the cutoff point, we operated the GEPIA2 to reveal the clinical outcome effect of gene expression on OS and DFS across TCGA cancers. The data were generated by the “Survival Map” and “Survival Analysis” modules and displayed as survival maps and log-rank survival plots, respectively. In parallel, according to the K-M plotter tool44, the prognosis implication of PSMA7 expression was also estimated using the log-rank test via the “mRNA genechip” module for breast, ovarian, lung, and gastric cancers (Affy ID for 201114_x_at), as well as the “mRNA RNA-seq” module for liver cancer (RNAseq ID for 5688), across the GEO cohorts. The “Auto select best cutoff” was regarded as the cutoff point. The survival indexes included OS, distant metastasis-free survival (DMFS), PFS, FP, RFS, PPS, and DSS. P values below 0.05 were recognized with statistical differences.
CRISPR-Cas9-mediated PSMA7 loss of function analysis
The Depmap database48 captured the data of the whole genome CRISPR knockout screens in exceeding 1000 cancer cell lines. With inputting the gene “PSMA7″, the “Perturbation Effects” module displayed the influence of PSMA7 depletion on cancer cell viability using the dataset of "CRISPR (DepMap Public 23Q2 + Score, Chronos)”. The data for the DepMap CRISPR dependency scores were visualized as box plots. A lower score indicates a higher likelihood that PSMA7 is essential in a given cell line. A score of 0 and -1 represents that PSMA7 is dispensable or comparable to the median of all pan-essential genes, respectively.
Enrichment analysis of PSMA7-related genes
By inputting “PSMA7”, we identified the PSMA7-interacting proteins with experimental evidence in the organism “Homo sapiens” via STRING online. The major filtered conditions were listed in the following: the definition of network boundaries limited by “evidence”, active interaction sources originated from “experiments”, “Low confidence (0.150)” selected for the smallest required interplay score, and “no more than 50 interactors” in 1st shell for showing maximum interactors.
Besides, the first 100 genes whose expressions were linked to PSMA7 were acquired in the “Similar Gene Detection” section of GEPIA2 by combining data from TCGA tumors and healthy volunteer samples. We then explored the potential link of PSMA7 expression to these chosen genes through the Pearson correlation test. The data were shown as dot plots with log2 TPM. In addition, via the Spearman rank correlation test, we further validated the association of these selected genes with PSMA7 expression in the “Gene_Corr” section of TIMER2. Finally, we interpreted the result into a heat diagram.
Moreover, we overlapped the aforementioned two gene sets by Jvenn49 to obtain the intersection genes. Subsequently, the union genes were subjected to the KEGG and GO enrichment analysis. Briefly, all genes were functionally annotated by DAVID (the database for annotation, visualization, and integrated discovery), under the filtered conditions of chosen identifier “OFFICIAL_GENE_SYMBOL” and species “Homo sapiens”. The final results for the KEGG enriched pathway and GO were presented as bubble charts and cnetplots with R languages, respectively. P values below 0.05 were recognized with statistical differences.
Potential PSMA7-resistant and sensitive drug screening
The GSCA web40 integrates the tumor data from diverse TCGA cancers and compounds exceeding 750 from the GDSC and CTRP databases. The “Drug” module was applied to reveal the relationship of PSMA7 expression with the IC50 representing the drug susceptibility. For resistant (R-value: positive) and sensitive (R-value: negative) agent analysis, the FDR values below 1.0e-5 and 0.05 were considered statistically significant in each. Intersection analysis via the Jvenn online tool was conducted to obtain the candidate PSMA7-resistant and sensitive compounds in GDSC and CTRP. The common potential agents were re-ranked by the sum of the R-value in both drug libraries. Additionally, the top 30 ranked compounds positively correlated with PSMA7 expression were visualized in GDSC and CTRP, respectively. The copy number data of cancer cell lines from COSMIC (Version 99, GRCh38)52 was applied to evaluate the potential association of PSMA7 CNAs with the sensitivity of specific compounds in GDSC and CTRP. Finally, the gene expression and copy number profile data from both drug libraries51 were used to analyze the possible relationship between PSMA7 expression and CNAs in cancer cell lines under detailed agent treatment by the correlation analysis and Kruslal-Wallis test.
Data availability
The data produced during the current research are attached in the issued main text and the additional files. All bioinformatics tools mentioned during the analysis process are public to access. Please contact shengesther@163.com if someone wants to request the data from this study.
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Acknowledgements
Here we gratefully thanked Dr. Lou Jiacheng (Blogger, WeChat official accounts: Chris_Life_Science) provided extremely constructive suggestions for manuscript revisions. This research was funded by the National Key R&D Program of China (2023YFA1800401 and 2019YFA0905902) and the National Natural Science Foundation of China (82350710226, 82370178 and 81890994).
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G.Y.S. raised and designed the research idea with KK.W.’s guidance. G.Y.S. and F.Y.L. did the bioinformatic analysis by online tool databases and R language, respectively. The bioinformatics data was interpreted by G.Y.S. and F.Y.L., G.Y.S. drafted the manuscript. The manuscript was revised and proofread by K.K.W. and W.J. And the final text was read and allowed by the aforementioned authors to submit for publication.
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Sheng, G., Li, F., Jin, W. et al. Pan-caner analysis identifies PSMA7 as a targets for amplification at 20q13.33 in tumorigenesis. Sci Rep 14, 3034 (2024). https://doi.org/10.1038/s41598-024-53585-0
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DOI: https://doi.org/10.1038/s41598-024-53585-0
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