Targeted TPX2 increases chromosome missegregation and suppresses tumor cell growth in human prostate cancer

Prostate cancer is a complex disease that can be relatively harmless or extremely aggressive. Although androgen-deprivation therapy is a commonly used treatment for men with prostate cancer, the adverse effects can be detrimental to patient health and quality of life. Therefore, identifying new target genes for tumor growth will enable the development of novel therapeutic intervention. TPX2 plays a critical role in chromosome segregation machinery during mitosis. Low rates of chromosome missegregation can promote tumor development, whereas higher levels might promote cell death and suppress tumorigenesis. Hence, the strategy of promoting cell death by inducing massive chromosome missegregation has been a therapeutic application for selectively eliminating highly proliferating tumor cells. RNAi was used for TPX2 protein expression knockdown, and a clonogenic assay, immunostaining, double thymidine block, image-cytometry analysis, and tumor spheroid assay were used to analyze the role of TPX2 in tumor cell growth, cell cycle progression, multinuclearity, ploidy, and tumorigenicity, respectively; finally, Western blotting was used to analyze anticancer mechanisms in TPX2 targeting. We demonstrated that targeting TPX2 reduced cell cycle regulators and chromosome segregation genes, resulting in increased cell micronucleation. Moreover, TPX2 depletion led to prostate cancer cell growth inhibition, increased apoptosis, and reduced tumorigenesis. These results confirmed the therapeutic potential of targeting TPX2 in prostate cancer treatment. Moreover, we found that TPX2 silencing led to deregulation of CDK1, cyclin B, securin, separase, and aurora A proteins; by contrast, p21 mRNA was upregulated. We also determined the molecular mechanisms for TPX2 targeting in prostate cancer cells. In conclusion, our study illustrates the power of TPX2 as a potential novel target gene for prostate cancer treatment.

[1]  H. Hsu,et al.  Overexpression of tumour-associated trypsin inhibitor (TATI) enhances tumour growth and is associated with portal vein invasion, early recurrence and a stage-independent prognostic factor of hepatocellular carcinoma. , 2007, European journal of cancer.

[2]  Pumin Zhang,et al.  Securin and separase phosphorylation act redundantly to maintain sister chromatid cohesion in mammalian cells. , 2005, Molecular biology of the cell.

[3]  Lauren M. Zasadil,et al.  Chromosome missegregation rate predicts whether aneuploidy will promote or suppress tumors , 2013, Proceedings of the National Academy of Sciences.

[4]  S. Hirohashi,et al.  Combined Functional Genome Survey of Therapeutic Targets for Hepatocellular Carcinoma , 2010, Clinical Cancer Research.

[5]  R. Medema,et al.  Elevating the frequency of chromosome mis-segregation as a strategy to kill tumor cells , 2009, Proceedings of the National Academy of Sciences.

[6]  D. Cleveland,et al.  Losing balance: the origin and impact of aneuploidy in cancer , 2012, EMBO reports.

[7]  R. Benezra,et al.  The cancer biology of whole-chromosome instability , 2013, Oncogene.

[8]  Guanqun Huang,et al.  Targeting TPX2 Suppresses the Tumorigenesis of Hepatocellular Carcinoma Cells Resulting in Arrested Mitotic Phase Progression and Increased Genomic Instability , 2017, Journal of Cancer.

[9]  O. Kallioniemi,et al.  High-Throughput Transcriptomic and RNAi Analysis Identifies AIM1, ERGIC1, TMED3 and TPX2 as Potential Drug Targets in Prostate Cancer , 2012, PloS one.

[10]  Y. Jeng,et al.  ASPM Is a Novel Marker for Vascular Invasion, Early Recurrence, and Poor Prognosis of Hepatocellular Carcinoma , 2008, Clinical Cancer Research.

[11]  A. Jemal,et al.  Global cancer statistics , 2011, CA: a cancer journal for clinicians.

[12]  E. Dmitrovsky,et al.  Anaphase Catastrophe Is a Target for Cancer Therapy , 2011, Clinical Cancer Research.

[13]  L. Fong,et al.  Neoadjuvant therapy for localized prostate cancer: Examining mechanism of action and efficacy within the tumor. , 2016, Urologic oncology.

[14]  C. Swanton,et al.  Cancer chromosomal instability: therapeutic and diagnostic challenges , 2012, EMBO reports.

[15]  F. Finkernagel,et al.  Induction of p21CIP1 Protein and Cell Cycle Arrest after Inhibition of Aurora B Kinase Is Attributed to Aneuploidy and Reactive Oxygen Species* , 2014, The Journal of Biological Chemistry.

[16]  T. Hirota,et al.  Separase sensor reveals dual roles for separase coordinating cohesin cleavage and cdk1 inhibition. , 2012, Developmental cell.

[17]  R. Parwaresch,et al.  p100: a novel proliferation-associated nuclear protein specifically restricted to cell cycle phases S, G2, and M. , 1997, Blood.

[18]  H. Hsu,et al.  Overexpression of osteopontin is associated with intrahepatic metastasis, early recurrence, and poorer prognosis of surgically resected hepatocellular carcinoma , 2003, Cancer.

[19]  Terence P. Speed,et al.  Identification of Candidate Growth Promoting Genes in Ovarian Cancer through Integrated Copy Number and Expression Analysis , 2010, PloS one.

[20]  Toru Hirota,et al.  Chromosome segregation machinery and cancer , 2009, Cancer science.

[21]  Hung-Wei Pan,et al.  Role of L2DTL, Cell Cycle-Regulated Nuclear and Centrosome Protein, in Aggressive HepatocellularCarcinoma , 2006, Cell cycle.

[22]  J. Millar,et al.  Sharpening the anaphase switch. , 2015, Biochemical Society transactions.

[23]  O. Gruss,et al.  Meiotic Regulation of TPX2 Protein Levels Governs Cell Cycle Progression in Mouse Oocytes , 2008, PloS one.

[24]  J. Trent,et al.  Validation of TPX2 as a Potential Therapeutic Target in Pancreatic Cancer Cells , 2009, Clinical Cancer Research.

[25]  Hannu Norppa,et al.  What do human micronuclei contain? , 2003, Mutagenesis.

[26]  G. Pond,et al.  Identification of small molecules that sensitize resistant tumor cells to tumor necrosis factor-family death receptors. , 2006, Cancer research.

[27]  Stephen S. Taylor,et al.  The Spindle Assembly Checkpoint , 2012, Current Biology.

[28]  John C Reed,et al.  Novel Phosphorylation and Ubiquitination Sites Regulate Reactive Oxygen Species-dependent Degradation of Anti-apoptotic c-FLIP Protein* , 2013, The Journal of Biological Chemistry.

[29]  J. Cerhan,et al.  Gene networks and microRNAs implicated in aggressive prostate cancer. , 2009, Cancer research.

[30]  B. Weaver,et al.  Does aneuploidy cause cancer? , 2006, Current opinion in cell biology.

[31]  J. Zajac,et al.  Androgens and prostate cancer; pathogenesis and deprivation therapy. , 2013, Best practice & research. Clinical endocrinology & metabolism.

[32]  D. Hanahan,et al.  Hallmarks of Cancer: The Next Generation , 2011, Cell.

[33]  Nicolai J. Birkbak,et al.  Chromosomal instability confers intrinsic multidrug resistance. , 2011, Cancer research.

[34]  A. Jemal,et al.  Global cancer statistics, 2012 , 2015, CA: a cancer journal for clinicians.

[35]  R. Medema,et al.  Genetic instability: tipping the balance , 2013, Oncogene.

[36]  T. Hirota,et al.  Chromosomal instability: A common feature and a therapeutic target of cancer. , 2016, Biochimica et biophysica acta.