|Year : 2019 | Volume
| Issue : 12 | Page : 531-538
Targets and molecular mechanisms of a citrus flavonoid, hesperidin, against luminal breast cancer cells: an integrative bioinformatics analysis
Adam Hermawan1, Herwandhani Putri2
1 Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Universitas Gadjah Mada, Sekip Utara II, 55281 Yogyakarta, Indonesia
2 Cancer Chemoprevention Research Center, Faculty of Pharmacy, Universitas Gadjah Mada, Sekip Utara II, 55281 Yogyakarta, Indonesia
|Date of Submission||12-Aug-2019|
|Date of Decision||17-Sep-2019|
|Date of Acceptance||18-Nov-2019|
|Date of Web Publication||11-Dec-2019|
Department of Pharmaceutical Chemistry, Faculty of Pharmacy, Universitas Gadjah Mada, Sekip Utara II, 55281 Yogyakarta
Source of Support: None, Conflict of Interest: None
Objective: To identify the potential target and mechanisms of hesperidin in MCF-7 estrogen receptor-positive breast cancer cells using bioinformatics approaches.
Methods: Gene expression profiles were accessed from public database GSE85871. Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment analysis was carried out with Database for Annotation, Visualization and Integrated Discovery. The protein-protein interaction network was analyzed by STRING-DB and visualized by Cytoscape. Transcription factor regulatory networks were constructed from TRED, TRRUST, RegNetwork and visualized by Cytoscape. Drug association analysis was conducted by WebGestalt.
Results: GO and KEGG pathway enrichment analysis revealed biological processes, cellular components and molecular functions that were related to cancer and estrogen signaling pathways. KEGG pathway enrichment analysis of the genes in transcription factor-differential expression genes regulatory network showed regulation of cancer, estrogen signaling pathways, epidermal growth factor receptor tyrosine kinase inhibitor resistance, and endocrine resistance. Moreover, drug association analysis revealed that hesperidin affected the expression of the same gene as raloxifene.
Conclusions: Hesperidin targets estrogen receptor signaling in estrogen receptor-positive breast cancer cells. Results of this study could trace the molecular mechanism of hesperidin in estrogen receptor-positive breast cancer cells and integrative bioinformatics analysis could accelerate drug discovery and development.
Keywords: Hesperidin, Breast cancer, Bioinformatics, Estrogen receptor, Signaling pathway
|How to cite this article:|
Hermawan A, Putri H. Targets and molecular mechanisms of a citrus flavonoid, hesperidin, against luminal breast cancer cells: an integrative bioinformatics analysis. Asian Pac J Trop Biomed 2019;9:531-8
|How to cite this URL:|
Hermawan A, Putri H. Targets and molecular mechanisms of a citrus flavonoid, hesperidin, against luminal breast cancer cells: an integrative bioinformatics analysis. Asian Pac J Trop Biomed [serial online] 2019 [cited 2022 Aug 9];9:531-8. Available from: https://www.apjtb.org/text.asp?2019/9/12/531/271727
| 1. Introduction|| |
Breast cancer is still the most commonly diagnosed and leading cause of cancer death among females worldwide. It is classified into five main molecular subtypes, namely luminal A [estrogen receptor (ER)+ and/or progesterone receptor (PR)+, human epidermal growth factor receptor (HER)-2 negative, Ki-67 < 14%], luminal B with HER-2 negative (ER+ and/or PR+, HER-2 negative, Ki-67 ≥ 14%), luminal B with HER-2 positive (ER+ and/or PR+, HER-2+, any Ki-67), HER-2 enriched (ER-, PR-, HER-2+), and basal-like (triple negative) [ER-, PR-, HER-2 negative, CK5/6+ and/or epidermal growth factor receptor (EGFR)+]. ER-positive cancer is the most common subtype of breast cancer that responds to endocrine therapy, i.e. selective ER modulators (SERMs), such as tamoxifen, selective ER downregulators, such as fulvestran, and aromatase inhibitors, such as letrozole. However, tamoxifen resistance in ER-positive breast cancer intrinsically occurs during treatment and causes a major impediment to successful therapy. Accordingly, therapeutic strategies to overcome tamoxifen resistance need to be developed.
Hesperidin [Supplementary Figure 1[Additional file 1]], a citrus flavonoid, is able to stimulate apoptosis and cell cycle arrest in several types of cancer such as colon and liver. It promotes apoptosis through increased expression of p53 and PPAR- γ and inhibition of NF- κ B activation in NALM-6 leukemia series. Combinatorial treatment of hesperidin and chemotherapeutics has been demonstrated in many studies. Hesperidin as adjuvant therapy with doxorubicin improves therapeutic efficacy and reduces tumor resistance to the latter. The hesperidin increases cytarabine cytotoxicity in leukemia cells, so it is potentially developed in acute myeloid leukemia therapy either as a single agent or in combination with cytarabine. Recent research has shown that hesperidin can reduce the rate of liver damage in mice treated with cisplatin in a dose-dependent manner. Hesperidin exerts a cytotoxic effect on doxorubicin-resistant MCF-7 breast cancer cells and has a synergistic effect with doxorubicin through inhibition of P-glycoprotein expression. Hesperidin has low cytotoxic activity in MCF-7 cells and produces a combination that is synergistic with doxorubicin. Nevertheless, the molecular mechanism of hesperidin in ER-positive breast cancer cells, e.g. MCF-7 cells, remains unclear.
Integrative bioinformatics approaches are widely used to accelerate drug discovery and development. In this study, we obtained microarray data from public databases, e.g. GEO datasets, to obtain differential expression genes (DEGs). Functional annotations were then carried out to predict molecular mechanisms, functions and roles of the DEGs. Furthermore, analysis of the protein-protein interaction (PPI) network was performed. Here we provided information about the possible molecular mechanisms of hesperidin and its molecular targets against ER-positive breast cancer cells. Taken together, we aimed to provide a more complete understanding of the targets and the molecular mechanism of hesperidin against ER-positive breast cancer cells using integrative bioinformatics approaches.
| 2. Materials and methods|| |
2.1. Data collection and processing
Data of mRNA was obtained from public database GSE85871, entitled, “The gene expression profiles in response to 102 traditional Chinese medicine (TCM) components: a general template for research on TCMs”. Briefly, MCF-7 cells were cultured as previously described and treated with 10 μM hesperidin for 24 h and dimethyl sulfoxide-treated cells were selected as a control. For RNA analysis, the cell viability should be higher than 40% as determined by MTT assay.
The gene expression profiles were assessed using microarray technology with Affymetrix Human Genome U133A 2.0 (Santa Clara, CA, US). Sampling distribution was good [Supplementary Figure 2[Additional file 2]]. Data processing was conducted using GEO2R, an online tool for GEO data analysis based on the R programming language. DEGs between hesperidin and DMSO-treated cells were screened. Adjusted P value < 0.05 and log2 fold change (FC)>1 were used to select significant DEGs. A total of 1 009 genes were extracted from GSE85871, consisting of 389 upregulated and 620 downregulated genes.
2.2. Functional annotation and pathway enrichment analysis
Analyses of Gene Ontology (GO) and Kyoto Encyclopedia of Genes and Genomes (KEGG) pathway enrichment were conducted by the Database for Annotation, Visualization and Integrated Discovery v6.8, with P < 0.05 selected as the cutoff value.
2.3. Construction of PPI network and cluster analysis
Analysis of PPI network was constructed with STRING-DB v11.0 with confidence scores > 0.9 and visualized by Cytoscape software (version 3.7.1). Genes with a degree greater than 10, analyzed by CytoHubba plugin, were selected as hub genes.
2.4. Transcription factor (TF)-DEGs regulatory network
TRED is a database of cancer-related TFs. TF-related cancer was searched among DEGs. The target genes from TFs were then predicted using the TRRUST and RegNetwork databases and searched among DEGs. TF regulatory network was visualized using Cytoscape software (version 3.7.1).
2.5. Drug association analysis
Predicted drugs with a similar mechanism to hesperidin were analyzed with Overrepresentation Enrichment Analysis (ORA) from WEB-based GEne SeT AnaLysis Toolkit (WebGestalt) with false discovery rate (FDR) < 0.05 as the cutoff value. Briefly, All genes in TF-DEGs regulatory networks were submitted to ORA from WebGestalt, with functional parameter DrugBank.
| 3. Results|| |
3.1. GO analysis of potential hesperidin target genes
To explore the biological process, cellular components, and molecular function of the DEGs, we performed GO analysis. Among the upregulated genes [Table 1], DEGs take part in the biological process of positive regulation of transcription, DNA-templated, cell adhesion, and positive regulation of cell cycle. The upregulated DEGs are located in the cell surface, extracellular matrix, poteinaceous extracellular matrix, and extracellular space. Moreover, the upregulated DEGs play a molecular function in protein homodimerization activity, calmodulin binding, growth factor activity, transcriptional coactivator activity and calcium ion binding.
The downregulated DEGs [Table 1] are involved in the biological process of immune response, cell-cell signaling, signal transduction, angiogenesis, and aging. The DEGs are located in integral components of the plasma membrane, extracellular space, extracellular region, and cell surface. Also, the downregulated DEGs play a role in protease binding, receptor binding, ion channel binding, cytokine activity, hormone activity, and estrogen response element binding.
3.2. KEGG pathway enrichment analysis
Pathway enrichment by KEGG of the upregulated genes [Table 2] showed the regulation of chemokine signaling pathways, ECM-receptor interaction, hematopoietic cell lineage, protein digestion and absorption, cytokine-cytokine receptor interaction, and pathways in cancer. In addition, the downregulated DEGs showed the regulation of signaling pathways such as calcium signaling pathway, neuroactive ligand-receptor interaction, type Π diabetes mellitus, Rap1 signaling pathway, and natural killer cell mediated cytotoxicity.
|Table 2: KEGG pathway enrichment of the upregulated and downregulated genes.|
Click here to view
3.3. PPI network construction and module selection
To examine the biological role of the DEGs, we constructed a PPI network using the STRING database. A total of 1 009 genes were constructed to the PPI network complex containing 867 nodes and 1 069 edges, with average node degree 2.47 [Supplementary Figure 3[Additional file 3]]. The 50 nodes with degree scores more than 10 were identified, mainly including PIK3R1, GNG11, ADAM10, KRAS, and ITGB3 [Figure 1], [Table 3].
|Table 3: Top 50 in protein network interactions ranked by Degree score method.|
Click here to view
|Figure 1: Protein network of top 50 genes with degree score more than 10, analyzed by CytoHubba.|
Click here to view
3.4. TF-DEGs regulatory network and pathway enrichment
To examine the transcriptional network of the DEGs, we created a TF-DEGs regulatory network. TRED is a database of cancer-related TF. Among DEGs, there are nine transcription factors found in TRED: TFAP2A, EGR4, ESR1, ESR2, HIF3A, MSX2, MYBL1, POU3F2, and RARA. Target genes of eight TFs were then predicted using TRRUST, except for EGR4 target genes, which were predicted using RegNetwork. There are 22 genes among DEGs which are target genes of ESR1, ESR2, TFAP2A and RARA. A TF regulatory network was then constructed and visualized by Cytoscape [Figure 2]. KEGG pathway enrichment analysis of the genes in the TF-regulatory network showed regulation of cancer, estrogen signaling pathway, EGFR tyrosine kinase inhibitor resistance, and endocrine resistance [Table 4].
|Figure 2: Transcription factors-differential expression genes regulatory network, analyzed by Cytoscape.|
Click here to view
|Table 4: KEGG enrichment pathway of DEGs involved in TF-regulatory network.|
Click here to view
3.5. Drug association analysis
The results showed one drug with FDR < 0.05, i.e. raloxifene, which has associated genes similar to hesperidin, thus indicating that raloxifene probably affects the expression of the same gene as hesperidin [Figure 3].
|Figure 3: Predicted drugs with similar mechanisms to hesperidin, analyzed by ORA, WebGestalt.|
Click here to view
| 4. Discussion|| |
This study identified the potential target and molecular mechanism of hesperidin in ER-positive breast cancer cells using bioinformatics approaches. GO enrichment analysis showed that upregulated DEGs affect the processes of cell adhesion, positive regulation of transcription, and the cell cycle. Upregulation of RARA promotes epithelial-to-mesenchymal transition, a phenomenon that occurs when cells lose cell-cell adhesion. The upregulated DEGs locate in a cellular component, cell surface, or extracellular matrix. A RARA present in membrane lipid rafts forms complexes with G protein to activate p38MAPK in cancer cells. The upregulated DEGs are involved in transcription coactivator activity. RARA and ERs can cooperate for effective transcriptional activity in breast cancer cells.
GO enrichment analysis of downregulated genes affects the biological process of cell-cell signaling, e.g. estrogen signaling. The downregulated DEGs are located in several cells, including the extracellular region, membrane raft, and membrane. TGFA encodes transforming growth factor alpha (TGF-α), a ligand which binds to EGFR in the cell membrane and stimulates tyrosine kinase signaling. The downregulated DEGs are involved in estrogen response element binding. The classical mechanism of estrogen signaling starts by binding the hormone to receptors in the nucleus, and continues with receptor dimerization and binding to specific response elements in the promoter of target genes called estrogen response elements. KEGG pathway enrichment analysis of the upregulated and downregulated genes showed regulation of pathways in cancer, and calcium signaling pathway and Rap1 signaling pathway, respectively. Rap1 signaling plays an essential role in cancer migration, invasion and metastasis.
PPI network indicated that more than 50 genes possess degree scores of more than ten. PIK3R1, GNG11, ADAM10, KRAS and ITGB3 are the top five genes with the highest degree scores. The expression level of PIK3R1, which encodes phosphoinositide-3-kinase regulatory subunit 1 and a constituent of the phosphoinositide 3-kinase, alters tamoxifen anti-proliferative activity in breast cancer cells. Overexpression of GNG11, which encodes guanine nucleotide-binding protein (G protein), subunit gamma-11, enhances epithelial-to-mesenchymal transition and migration of breast cells toward malignant phenotypes. ADAM10 encodes a disintegrin and metalloproteinase domain-containing protein 10, and is also known as ADAM 10, a member of the ADAM family, which is involved in breast cancer progression, especially of the basal subtype.
Activation of ADAM10, which is mediated by ER signaling, promotes anti-amyloidogenic processing of amyloid precursor protein in Alzheimer’s disease in mice. KRAS (Kirsten rat sarcoma viral oncogene homolog) is a viral oncogene and a member of the RAS superfamily of proteins which play a role in intracellular signaling associated with carcinogenesis. KRAS-activating mutations activate estrogen signaling in endometrial cancer. ITGB3 encodes integrin subunit beta 3 which increases proliferation, migration, and invasion of non-small cell lung cancer. Activation of ER signaling promotes estrogen receptor-positive breast cancer invasion by enhancing the expression of integrin β 3. Collectively, those genes are involved in the estrogen signaling pathway. There has been no study to date of those genes in hesperidin-treated ERpositive breast cancer cells yet,.
TF-DEGs regulatory network results showed that there are 4 TFs associated with the effects of hesperidin: ESR1, ESR2, TFAP2A and RARA. TFAP2B encodes transcription factor AP-2 β (TFAP2B) which regulates embryonic organ development and is overexpressed in alveolar rhabdomyosarcoma, a rare childhood malignancy and invasive lobular breast cancer. More importantly, KEGG pathway enrichment analysis of the TF-DEGs regulatory network showed regulation of pathway in cancer, estrogen signaling, EGFR tyrosine kinase inhibitor resistance and endocrine resistance by hesperidin. Binding of estrogen to the ER, a nuclear TF, leads to specific binding to the DNA sequence, called the estrogen response element, and induces expression of estrogen-responsive genes. AKT and MAPK signaling regulate the resistance mechanism of EGFR tyrosine kinase inhibitor. Resistance to gefitinib, an EGFR tyrosine kinase inhibitor in breast cancer, is regulated by MEK/MAPK pathway and AKT signaling pathway. In addition, breast cells can become EGFR-TKI resistant due to the interaction of FAM83A and phosphorylation of c-RAF and PI3K p85, upstream of MAPK and downstream of EGFR. A review conducted by Arpino et al. demonstrated that the molecular mechanism of resistance to anti-estrogen therapy, specifically tamoxifen, is associated with increased expression and signaling of EGFR and HER2, as well as a cross-link between EGFR and ER signaling. Endocrine therapy resistance is associated with TFAP2C since it regulates EGFR and HER2 signaling in luminal breast cancer. Accordingly, those genes are involved in ER signaling. However, analysis of the transcriptional regulatory network of those genes in hesperidin-treated ER-positive breast cancer cells has never been done before.
Drug association analysis showed that raloxifene affects the expression of the same gene as hesperidin. Raloxifene is a selective ER modulator which is antagonistic to ERs in the mammary gland and uterus, and is used to reduce the risk of breast and ovarian cancer. The drug produces estrogen-agonist effects in the skeleton and cardiovascular system and is used to prevent osteoporosis in menopausal women. Raloxifene shows slightly lower efficacy but better safety than tamoxifen in breast cancer. Therefore, hesperidin has the potential as a SERM, although further research is needed.
The present study indicates that hesperidin regulates estrogen signaling and exhibits similar actions as endoxifen as a SERM. A previous study showed that hesperidin had no cytotoxicity on MCF-7 cells at concentrations up to 100 μM over 24 h treatment[ 12]. Another study has demonstrated that hesperidin at a concentration of 100 μM inhibits the proliferation of MCF-7-GFP-Tubulin cells after 72 h treatment. In addition, a recent study showed hesperidin cytotoxicity on MCF-7 cells with IC50 of 9.35 μM at 48 h treatment. Treatment of hesperidin using the same concentration in endometrial cancer cells at 48 h and 72 h showed cytotoxicity and induction of apoptosis. Recently, nanoformulation of hesperidin inhibited cell proliferation and induced p53-dependent apoptosis after 48 h treatment in MCF-7 cells. It exhibits not only cytotoxicity, but also immunomodulatory effect with a good safety profile based on acute and a sub-chronic oral toxicity study in Sprague Dawley rats. To be brief, the present study supports and highlights the development of hesperidin as an anticancer drug that targets ER-positive breast cancer.
Using integrated bioinformatics approaches, this present study found that hesperidin targeted estrogen signaling in luminal breast cancer cells. The results not only contribute to the latest research data but also reveal potential targets for the treatment of ER-positive breast cancer. Genes associated with TFs can be used as biomarkers and for measuring clinical outcomes of hesperidin. More importantly, results of this study can be used as a reference for further work to explore the potential of hesperidin in overcoming the resistance of EGFR tyrosine kinase inhibitors and endocrine, as well as a basis for the development of hesperidin as a SERM. However, this study has several limitations. The data used for PPI network analysis is mRNA, not protein expression data. It is possible to obtain different results when using DEGs from protein expression data because not every mRNA will be translated into protein. The results of this study will also need to be validated in vitro and in vivo to determine the mechanism of hesperidin in ER-positive breast cancer.
In summary, hesperidin targets ER signaling in ER-positive breast cancer cells. In vitro and in vivo experiments are needed to validate the results and find out more about the role of these genes in the effectiveness of hesperidin. Future studies are also needed to explore the full therapeutic potential of hesperidin against EGFR tyrosine kinase inhibitor and endocrine resistance.
Conflict of interest statement
The authors declare that there is no conflict of interest.
This work was supported by Penelitian Unggulan Perguruan Tinggi (PUPT) 2017 and 2018 Contract No. 2398/UN1.P.III/DIT-LIT/ LT/2017 and No.189/UN1/DITLIT/DIT-LIT/LT/2018.
AH contributed in conception and design of the study, acquisition, analysis and interpretation of data, drafting and revising the article and final approval of the version to be published. HP contributed to analysis of data, drafting the article and final approval of the version to be published.
| References|| |
Bray F, Ferlay J, Soerjomataram I, Siegel RL, Torre LA, Jemal A. Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries. CA Cancer J Clin
Kondov B, Milenkovikj Z, Kondov G, Petrushevska G, Basheska N, Bogdanovska-Todorovska M, et al. Presentation of the molecular subtypes of breast cancer detected by immunohistochemistry in surgically treated patients. Open Access Maced J Med Sci
Abdel-Hafiz HA. Epigenetic mechanisms of tamoxifen resistance in luminal breast cancer. Diseases
(3): 16. Doi:10.3390/diseases5030016.
Hultsch S, Kankainen M, Paavolainen L, Kovanen RM, Ikonen E, Kangaspeska S, et al. Association of tamoxifen resistance and lipid reprogramming in breast cancer. BMC Cancer
850. Doi: 10.1186/ s12885-018-4757-z.
Sivagami G, Vinothkumar R, Bernini R, Preethy CP, Riyasdeen A, Akbarsha MA, et al. Role of hesperetin (a natural flavonoid) and its analogue on apoptosis in HT-29 human colon adenocarcinoma cell line-- a comparative study. Food Chem Toxicol
Yumnam S, Hong GE, Raha S, Saralamma VV, Lee HJ, Lee WS, et al. Mitochondrial dysfunction and Ca(2+) overload contributes to hesperidin induced paraptosis in hepatoblastoma cells, HepG2. J Cell Physiol
Ghorbani A, Nazari M, Jeddi-Tehrani M, Zand H. The citrus flavonoid hesperidin induces p53 and inhibits NF-κ B activation in order to trigger apoptosis in NALM-6 cells: Involvement of PPAR γ -dependent mechanism. Eur J Nutr
Khedr NF, Khalil RM. Effect of hesperidin on mice bearing Ehrlich solid carcinoma maintained on doxorubicin. Tumour Biol
Desai UN, Shah KP, Mirza SH, Panchal DK, Parikh SK, Rawal RM. Enhancement of the cytotoxic effects of Cytarabine in synergism with Hesperidine and Silibinin in Acute Myeloid Leukemia: An in-vitro
approach. J Cancer Res Ther
Omar HA, Mohamed WR, Arafa ESA, Shehata BA, Sherbiny GA, Arab HH, et al. Hesperidin alleviates cisplatin-induced hepatotoxicity in rats without inhibiting its antitumor activity. Pharmacol Rep
Febriansah R, Putri DD, Sarmoko, Nurulita NA, Meiyanto E, Nugroho AE. Hesperidin as a preventive resistance agent in MCF-7 breast cancer cells line resistance to doxorubicin. Asian Pac J Trop Biomed
Hermawan A, Meiyanto E, Susidarti RA. Hesperidin increase cytotoxic effect of doxorubicin in MCF-7 cells. Indones J Pharm
Lv C, Wu X, Wang X, Su J, Zeng H, Zhao J, et al. The gene expression profiles in response to 102 traditional Chinese medicine (TCM) components: A general template for research on TCMs. Sci Rep
(1): 352. Doi: 10.1038/s41598-017-00535-8.
Huang DW, Sherman BT, Lempicki RA. Bioinformatics enrichment tools: Paths toward the comprehensive functional analysis of large gene lists. Nucleic Acids Res
Szklarczyk D, Franceschini A, Wyder S, Forslund K, Heller D, Huerta-Cepas J, et al. STRING v10: Protein-protein interaction networks, integrated over the tree of life. Nucleic Acids Res
(Database issue): D447-452.
Jiang C, Xuan Z, Zhao F, Zhang MQ. TRED: A transcriptional regulatory element database, new entries and other development. Nucleic Acids Res
(Database issue): D137-140.
Han H, Cho JW, Lee S, Yun A, Kim H, Bae D, et al. TRRUST v2: An expanded reference database of human and mouse transcriptional regulatory interactions. Nucleic Acids Res
Liu ZP, Wu C, Miao H, Wu H. RegNetwork: An integrated database of transcriptional and post-transcriptional regulatory networks in human and mouse. Database
Wang J, Vasaikar S, Shi Z, Greer M, Zhang B. WebGestalt 2017: A more comprehensive, powerful, flexible and interactive gene set enrichment analysis toolkit. Nucleic Acids Res
Doi A, Ishikawa K, Shibata N, Ito E, Fujimoto J, Yamamoto M, et al. Enhanced expression of retinoic acid receptor alpha (RARA) induces epithelial-to-mesenchymal transition and disruption of mammary acinar structures. Mol Oncol
Piskunov A, Rochette-Egly C. A retinoic acid receptor RARalpha pool present in membrane lipid rafts forms complexes with G protein alphaQ to activate p38MAPK. Oncogene
Ross-Innes CS, Stark R, Holmes KA, Schmidt D, Spyrou C, Russell R, et al. Cooperative interaction between retinoic acid receptor-alpha and estrogen receptor in breast cancer. Genes Dev
Singh B, Carpenter G, Coffey RJ. EGF receptor ligands: Recent advances. F1000Res
Bjornstrom L, Sjoberg M. Mechanisms of estrogen receptor signaling: Convergence of genomic and nongenomic actions on target genes. Mol Endocrinol
Zhang YL, Wang RC, Cheng K, Ring BZ, Su L. Roles of Rap1 signaling in tumor cell migration and invasion. Cancer Biol Med
Gelsomino L, Gu G, Rechoum Y, Beyer AR, Pejerrey SM, Tsimelzon A, et al. ESR1 mutations affect anti-proliferative responses to tamoxifen through enhanced cross-talk with IGF signaling. Breast Cancer Res Treat
Kosr MA, Ju D. The CXCL7/CXCR2 axis and the migration of breast cells toward the malignant phenotype. J Clin Oncol
(27_suppl): 181. Doi: 10.1200/jco.2012.30.27_suppl.181.
Mullooly M, McGowan PM, Kennedy SA, Madden SF, Crown J, O’ Donovan N, et al. ADAM10: A new player in breast cancer progression? Br J Cancer
Zhang SQ, Sawmiller D, Li S, Rezai-Zadeh K, Hou H, Zhou S, et al. Octyl gallate markedly promotes anti-amyloidogenic processing of APP through estrogen receptor-mediated ADAM10 activation. PLoS One
(8): e71913. Doi: 10.1371/journal.pone.0071913.
Birkeland E, Wik E, Mjøs S, Hoivik EA, Trovik J, Werner HMJ, et al. KRAS gene amplification and overexpression but not mutation associates with aggressive and metastatic endometrial cancer. Br J Cancer
Ring KL, Yates MS, Schmandt R, Onstad M, Zhang Q, Celestino J, et al. Endometrial cancers with activating KRas mutations have activated estrogen signaling and paradoxical response to MEK inhibition. Int J Gynecol Cancer
Ni R, Huang Y, Wang J. miR-98 targets ITGB3 to inhibit proliferation, migration, and invasion of non-small-cell lung cancer. Onco Targets Ther
Chi Y, Huang S, Wang L, Zhou R, Wang L, Xiao X, et al. CDK11p58 inhibits ER α -positive breast cancer invasion by targeting integrin β 3 via
the repression of ER α signaling. BMC Cancer
(1): 577. Doi: 10.1186/1471-2407-14-577.
Raap M, Gronewold M, Christgen H, Glage S, Bentires-Alj M, Koren S, et al. Lobular carcinoma in situ and invasive lobular breast cancer are characterized by enhanced expression of transcription factor AP-2beta. Lab Invest
Maiello MR, D’Alessio A, De Luca A, Carotenuto A, Rachiglio AM, Napolitano M, et al. AZD3409 inhibits the growth of breast cancer cells with intrinsic resistance to the EGFR tyrosine kinase inhibitor gefitinib. Breast Cancer Res Treat
Lee SY, Meier R, Furuta S, Lenburg ME, Kenny PA, Xu R, et al. FAM83A confers EGFR-TKI resistance in breast cancer cells and in mice. J Clin Inves
Arpino G, Wiechmann L, Osborne CK, Schiff R. Crosstalk between the estrogen receptor and the HER tyrosine kinase receptor family: Molecular mechanism and clinical implications for endocrine therapy resistance. Endocr Rev
De Andrade JP, Park JM, Gu VW, Woodfield GW, Kulak MV, Lorenzen AW, et al. EGFR is regulated by TFAP2C in luminal breast cancer and is a target for vandetanib. Mol. Cancer Ther
Rey JRC, Cervino EV, Rentero ML, Crespo EC, Alvaro AO, Casillas M. Raloxifene: Mechanism of action, effects on bone tissue, and applicability in clinical traumatology practice. Open Orthop J
Gennari L, Merlotti D, Paola VD, Nuti R. Raloxifene in breast cancer prevention. Expert Opin Drug Saf
Provinciali N, Suen C, Dunn BK, DeCensi A. Raloxifene hydrochloride for breast cancer risk reduction in postmenopausal women. Expert Rev Clin Pharmacol
Lee CJ, Wilson L, Jordan MA, Nguyen V, Tang J, Smiyun G. Hesperidin suppressed proliferations of both human breast cancer and androgen-dependent prostate cancer cells. Phytother Res
(Suppl 1): S15-19.
Le Bail JC, Varnat F, Nicolas JC, Habrioux G. Estrogenic and antiproliferative activities on MCF-7 human breast cancer cells by flavonoids. Cancer Lett
Cincin ZB, Kiran B, Baran Y, Cakmakoglu B. Hesperidin promotes programmed cell death by downregulation of nongenomic estrogen receptor signalling pathway in endometrial cancer cells. Biomed Pharmacother
Ali SH, Sulaiman GM, Al-Halbosiy MMF, Jabir MS, Hameed AH. Fabrication of hesperidin nanoparticles loaded by poly lactic co-Glycolic acid for improved therapeutic efficiency and cytotoxicity. Artif Cells Nanomed Biotechnol
Yeh CC, Kao SJ, Lin CC, Wang SD, Liu CJ, Kao ST. The immunomodulation of endotoxin-induced acute lung injury by hesperidin in vivo
and in vitro. Life Sci
Li Y, Kandhare AD, Mukherjee AA, Bodhankar SL. Acute and sub-chronic oral toxicity studies of hesperidin isolated from orange peel extract in Sprague Dawley rats. Regul Toxicol Pharmacol
[Figure 1], [Figure 2], [Figure 3]
[Table 1], [Table 2], [Table 3], [Table 4]