Gene Screening of Astrocytoma Grade III Relative to Grade II via Network Analysis: A New Molecular Insight

authors:

avatar Mostafa Rezaei-Tavirani ORCID 1 , * , avatar Sina Rezaei Tavirani 1

Proteomics Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran

how to cite: Rezaei-Tavirani M , Rezaei Tavirani S. Gene Screening of Astrocytoma Grade III Relative to Grade II via Network Analysis: A New Molecular Insight. Int J Cancer Manag. 2018;11(11):e83201. https://doi.org/10.5812/ijcm.83201.

Abstract

Background:

Astrocytomas (sub-group of gliomas) are central neuron system malignant diseases, which are originated from astrocytes. There are several documents about molecular mechanism of astrocytomas and many related genes are introduced. Here, gene expression profile alteration for grade III relative to grade II of astrocytoma is analyzed via protein-protein interaction (PPI) network to screen and introduce critical differentially expressed genes (DEGs).

Methods:

The significant DEGs were extracted from gene expression omnibus (GEO) database and included in a PPI network by Cytoscape software. The common significant DEGs and central nodes of the network were selected and enriched by ClueGO to find related biological terms.

Results:

Twenty critical genes including zinc finger protein 765 (ZNF765), zinc finger protein 540 (ZNF540), Zeste white 10 (ZW10) ZW10 interacting kinetochore protein (ZWINT), collagen type XVIII alpha 1 chain (COL18A1), protamine 2 (RRM2), kinesin family member 23 (KIF23), minichromosome maintenance 10 (MCM10), anaphase promoting complex subunit 7 (ANAPC7), NADPH oxidase activator 1 (NOXA1), ryanodine receptor 2 (RYR2), myozenin 3 (MYOZ3), myosin binding protein C (MYBPC2), fast type, keratin 17 (KRT17), zinc phosphodiesterase ELAC protein 2 (ELAC2), Abelson helper integration site 1 (AHI1), latent transforming growth factor beta binding protein 1 (LTBP1), kaptin (actin binding protein) (KPTN), BEN domain containing 3 (BEND3), cysteine and histidine rich 1 (CYHR1), and hyaluronoglucosaminidase 2 (HYAL2) were identified. Eight class of biological terms related to the critical genes were determined and discussed.

Conclusions:

A wide range of the introduced significant genes indicates that there are several possible therapeutic ways to challenge astrocytoma.

1. Background

As central neuron system (CNS) cancers, astrocytomas are considered as common glial tumors (1). Grade II (diffused astrocytoma) of this disease is characterized by slow developing tumor¸ considerable cell differentiation, and affinity to malignancy evolution (2). An investigation indicates that grade II astrocytoma frequently is diagnosed in 35-year-old patients (range of 20 - 45) (3). Anaplastic astrocytoma (grade III) is more malignant glioma than grade II (4). One year and 5 years survival for anaplastic astrocytoma patients is estimated at 75% and 25%, respectively (5). Low-grade gliomas (grade II gliomas) in adults include 3 groups as astrocytomas, oligodendrogliomas, and oligo-astrocytomas. Differences between the introduced groups are arisen from cellular origination of them. The low-grade disease tends to convert into higher grades (grades III and IV) (6). As it is reported, mutation frequency in astrocytoma grade III for isocitrate dehydrogenase 1 (IDH1), alpha-thalassemia/mental retardation syndrome, nondeletion type, X-linked (ATRX), and Tumor protein 53(TP53) genes are as 75%, 63%, and 82%, respectively (7). Details of up-regulation of ribosomal proteins S2, 8, S18, and L37A and down-regulation of apolipoprotein D (APOD), Sortilin-related receptor, L(DLR class) A (SORL1), SPARC (Osteonectin), Cwcv and Kazal like domains proteoglycan 2 (SPOCK2), protease, serine, 11 (PRSS11), DNA-binding protein inhibitor ID-3 (ID3) genes in the higher grades of asrtrocytoma are reported by MacDonald et al. (8). Kunkle et al. investigation displayed that deregulation of collagen type IV A1(COL4A1), epidermal growth factor receptor (EGFR), basic transcription factor 3(BTF3), MAGUK p55 subfamily member 2 (MPP2), RAS oncogene GTPases 31 (RAB31), cyclin-dependent kinase 4 (CDK4), cluster of differentiation 99 (CD99), annexin A2 (ANXA2), DNA topoisomerase II alpha (TOP2A), and SERPINE1 mRNA binding protein 1 (SERBP1) genes is related to the high grade of astrocytoma. They showed that except MPP2, the other genes were up-regulated (9). Recently, the screening of numerous genes to find restricted numbers of the critical genes, which are involved in diseases via PPI network analysis, has attracted the attention of researchers (10-12). Since the progression of lower grades of astrocytoma to higher grades is accompanied by difficulty of treatment and reduction of survival rate, here DEGs between grades II and III astrocytoma are investigated via PPI network analysis. The critical genes and related biological terms will determine to introduce therapeutic and diagnostic possible biomarkers.

2. Methods

Array gene expression profiles were used from series GSE54004 of GPL18281 platform (www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE54004). Six grade II astrocytoma patients including 3 males and 3 females and 21 grade III astrocytoma patients including 8 males and 13 females ranged 20 to 50 years old were included in the research.

This platform is recorded by “gene expression data from malignant gliomas” title in GEO database. As it is reported, the samples were formalin-fixed and paraffin-embedded. The profiles were matched by box plot examination via GEO2R analysis and the top 250 significant DEGs were determined. The unknown DEGs were excluded and P value less than 0.05 and fold change (FC) above 2 were considered. The screened DEGs were included to construct PPI network via Cytoscape version 3.6.0 (13). The network was constructed via public database query of Cytoscape and analyzed by “network analyzer”, which is an application of Cytoscape. The top nodes based on degree value above mean ± standard deviation (SD) were identified as hub-genes (14). The common hubs and significant DEGs were marked as critical genes, which distinct grades II and III of astrocytoma. The critical genes were enriched via gene ontology (GO) analysis by CluGO plugin of Cytoscape software (15). The related significant (P < 0.05) biological processes, molecular function, cellular component, and biochemical pathways were determined from all databases, which were connected to ClueGO.

3. Results

Comparing grades II and III astrocytoma patient samples, box plot is shown in Figure 1. Based on the midlines, the samples are matched statistically and can be compared. Forty-five significant DEGs were included in the PPI network. The created network was comprised of 4 489 nodes (45 query genes plus 4 444 related neighbors). Fitted power law of degree distribution (Figure 2) was characterized by y = axb equation that a, b, R-squared, and correlation were 85.147, -0.985, 0.637, and 0.898, respectively. The R-squared is calculated based on logarithmized values. This mode of correlation consists to the scale-free networks (16). There are limited numbers of nodes in scale-free networks, which are central nodes. PPI networks are usually scale-free network; therefore, few nodes among numerous nodes are distinguishable. The numbers of 50 nodes were determined as hubs of the network. There were 20 common hub-nodes and significant DEGs that were identified as critical genes. Degree and logarithm of FC of the critical genes are illustrated in Table 1. The significant (P < 0.05) GO enriched properties of the 20 critical genes, which are classified in the 8 groups, are shown in Figure 3.

Table 1.

Degree Value and Log FC of Common 20 Hubs and Significant DEGsa

RGene NameDegreeLog FC
1ZNF7654151.285
2ZNF540401-1.168
3ZWINT1971.073
4COL18A1132-1.137
5RRM21281.106
6KIF23941.059
7MCM10871.161
8ANAPC7761.021
9NOXA168-1.354
10RYR268-1.026
11MYOZ367-1.113
12MYBPC263-1.345
13KRT1759-1.076
14ELAC2511.074
15AHI145-1.246
16LTBP1451.038
17KPTN39-1.034
18BEND3361.141
19CYHR1321.026
20HYAL2281.054
Box plot presentation of gene expression profiles of 6 (3 males and 3 females) grade II and 21 (8 males and 13 females) grade III astrocytoma patients is illustrated. The patients were aged 20 to 50 years old. Formalin-fixed and paraffin-embedded samples were used.
Box plot presentation of gene expression profiles of 6 (3 males and 3 females) grade II and 21 (8 males and 13 females) grade III astrocytoma patients is illustrated. The patients were aged 20 to 50 years old. Formalin-fixed and paraffin-embedded samples were used.
Degree distribution curve of PPI network of grade III astrocytoma versus grade II is represented. The fitted power law is red colored.
Degree distribution curve of PPI network of grade III astrocytoma versus grade II is represented. The fitted power law is red colored.
Eight significant (P < 0.05) biological term including classified biological processes, molecular function, cellular component, and biochemical pathways related to the 20 critical genes of astrocytoma grade III versus grade II are shown.
Eight significant (P < 0.05) biological term including classified biological processes, molecular function, cellular component, and biochemical pathways related to the 20 critical genes of astrocytoma grade III versus grade II are shown.

4. Discussion

Since the conversion of low grades to higher grades is accompanied by a reduction of patient’s survival rate, a better understanding of molecular features of this transition is an important process. In this regard, PPI network analysis is a suitable method to highlight the critical and effective genes related to conversion of grade II to III of astrocytoma. As depicted in the Figure 1, the patient’s gene expression profiles of the two groups (grades II and III) are comparable. Among numerous DEGs, only 45 genes were significantly investigable. PPI network analysis showed without considering the neighbors and relevant genes, the 45 DEGs cannot construct a network (the data was not shown). To screen the DEGs, the related genes were found among various databases. As it is shown in the Figure 2, the constructed network by adding 4,444 genes is a scale-free network. Investigations indicate that central nodes in the scale-free networks are important reagents to onset and development of diseases (17). Fifty hubs were identified for grade II to grade III transition.

Considering two important futures including physicochemical properties and the expression level of the 45 significant DEGs and 50 hubs led to select 20 common hub nodes and significant DEGs (Table 1). So, the determined 20 critical genes that are involved in transition process of the both grades are as follow: Zinc finger protein 765, zinc finger protein 540, Zeste white 10 (ZW10) ZW10 interacting kinetochore protein, collagen type XVIII alpha 1 chain, protamine 2, kinesin family member 23, minichromosome maintenance 10, anaphase promoting complex subunit 7, NADPH oxidase activator 1, ryanodine receptor 2, myozenin 3, myosin binding protein C, fast type, keratin 17, zinc phosphodiesterase ELAC protein 2, Abelson helper integration site 1, latent transforming growth factor beta binding protein 1, kaptin (actin binding protein), BEN domain containing 3, cysteine, histidine rich 1, and hyaluronoglucosaminidase 2. For better understanding the biological role and also importance of the top 15 critical genes based on degree value is investigated in the literature sources and briefly is discussed.

Zinc finger proteins (ZNFs) are a family of various proteins, who are characterized by different cellular function. ZNFs can bind to DNA and proteins by various domains (18). The role of ZWINT in mitotic process in cell proliferation is reported and discussed. Deregulation of this gene in cancer cells is investigated and confirmed (19). The prominent role of ZNFs in cancer progression is highlighted by several researches (20). Myozenin 3 and myosin binding protein C belong to skeletal muscle cells and also intracellular complexes, which are responsible for contractile process (21). Collagen Type XVIII is a component of extracellular matrix in liver that its level in fibrotic damage, cirrhosis, and cancer is altered (22). Investigation has shown that human collagen type I α1 gene acts as growth suppressor in the glioma cells (23). Therefore, down-regulation of collagen type 1 in grade III astrocytoma relative to grade II (Table 1) can be interpreted based on absence or decrease of a growth suppressor reagent in the grade III astrocytoma patients versus grade IIs. The role of PRM2 and PRM1 in sperm production is investigated and confirmed (24). Investigation has shown over-expression of KIF23 and KIF11 in malignant pleural mesothelioma (MPM) as well as human MPM cell line (25). The presence of KRT17 in oral squamous cell carcinoma is confirmed via immunohistochemistry and cDNA array methods (26). NADH oxidase is introduced as an essential member of oxygen-derived radicals, which is related to the vascular walls (27). MCM10, the other critical gene, is involved in DNA unwinding. This protein, together with several elements as capillary morphogenesis gene (CMG) complex, administrates its biological role (28). The role of ELAC2 gene together with TGFβ/Smad-induced transcriptional response in prostate cancer promotion is investigated (29). RyR2 plays a critical role to couple of excitation-contraction in cardiomyocytes (30). One of the critical genes is AHI1, which is related to retinitis pigmentosa disease (31). ANAPC7 is complicated in mitotic progression in eukaryotes (32).

As it was discussed, most of the critical genes are involved in the regulation of DNA duplication and cell proliferation processes. Muscular compartment also was the highlighted cellular component related to the hub-DEGs.

Based on the results of gene ontology analysis, which is illustrated in the Figure 3, 8 classes of biological terms related to the 20 critical genes are identified. The main class is positive regulation of polarized epithelial cell differentiation. This finding consists of the discussed documents as references 10 to 22. Finally, it seems that as like as the other kinds of cancers, the regulation of cell proliferation and DNA duplication are the key points of grade II to grade III conversion of astrocytoma.

4.1. Conclusions

Introducing 20 critical genes as a biomarker panel was related to conversion of grade II to grade III of astrocytoma includes; first a challenge of numerous proposed biomarker candidate, which implies more screening to achieve a few numbers of biomarkers, and second the numerous proposed reagents can be useful to experience effective therapeutic and diagnostic procedures. The introduced crucial genes are potentially biomarkers of transitional phase from grade II to III.

Acknowledgements

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