[Retracted] Correlation of SOX9 and NM23 genes with the incidence and prognosis of prostate cancer.

[This retracts the article DOI: 10.3892/ol.2018.9828.].

Correlation of SOX9 and NM23 genes with the incidence and prognosis of prostate cancer.

Correlation of sex determining region Y-box (SOX)9 and NM23 genes with the incidence and prognosis of prostate cancer (PC) was investigated. SOX9-small interfering ribonucleic acid (siRNA) and NM23-siRNA were constructed and transfected into PC-3 cells. The expression levels of SOX9 and NM23 messenger RNAs (mRNAs) and proteins in PC-3 cells were detected via reverse transcription-quantitative polymerase chain reaction (RT-qPCR) and western blotting. MTT assay was adopted to examine the proliferation ability of the transfected cells, and Transwell assay was applied to detect the migration ability of the transfected cells. Sixty-three patients with PC and 56 patients with benign prostatic hyperplasia who were treated in Huadu District People's Hospital were enrolled. Correlation analyses were conducted for the relative expression levels of SOX9 and NM23 and the Gleason grade; and the survival curves of the patient SOX9/NM23 (S/N) Cq values were plotted. The proliferation and migration abilities of PC-3 cells were remarkably reduced after low expression of SOX9 (P<0.01), while those of PC-3 cells were significantly improved after low expression of NM23 (P<0.01). Compared with that in tissues of PC patients, the relative expression of SOX9 mRNA in patients with benign prostatic hyperplasia was obviously decreased (P<0.01), while that of NM23 mRNA was significantly elevated (P<0.01). The larger the S/N was, the shorter the patient's survival time would be (P<0.05). The low expression of SOX9 gene can significantly reduce the proliferation and migration abilities of PC cells, which is negatively associated with the incidence and prognosis of patients. The low expression of NM23 gene can markedly enhance the proliferation and migration abilities of PC cells, and it is positively related to the incidence and prognosis of patients.

Non-equilibrium plasma jet induced thermo-acoustic resistivity imaging for higher contrast and resolution.

A thermo-acoustic imaging modality induced by non-equilibrium atmospheric pressure plasma jet is reported. A tiny plasma jet is generated by a fast-rising pulsed dielectric barrier discharge and applied to the surface of the biological tissues. The pulsed conductive current induced by the conductive plasma jet is injected into the biological tissues. The Joule heating inside the tissue stimulates the ultrasound signals effectively. The amplitude of the ultrasound is related to the resistivity of the biological tissues near the contact point and takes the maximum at the certain conductivity of the certain frequency. Accordingly the thermo-acoustic resistivity imaging modality of high contrast and resolution is demonstrated theoretically and experimentally.

Enhancing DPYSL3 gene expression via a promoter-targeted small activating RNA approach suppresses cancer cell motility and metastasis.

To explore a novel strategy in suppressing tumor metastasis, we took the advantage of a recent RNA activation (RNAa) theory and used small double-strand RNA molecules, termed as small activating RNAs (saRNA) that are complimentary to target gene promoter, to enhance transcription of metastasis suppressor gene. The target gene in this study is Dihydro-pyrimidinase-like 3 (DPYSL3, protein name CRMP4), which was identified as a metastatic suppressor in prostate cancers. There are two transcriptional variants of DPYSL3 gene in human genome, of which the variant 2 is the dominant transcript (DPYSL3v2, CRMP4a) but is also significantly down-regulated in primary prostate cancers. A total of 8 saRNAs for DPYSL3v1 and 14 saRNAs for DPYSL3v2 were tested in multiple prostate cancer cell lines. While none of the saRNAs significantly altered DPYSL3v1 expression, 4 saRNAs showed a strong enhancing effect on DPYSL3v2 expression, resulting in reduced cell mobility in vitro. To achieve a prostate cancer-specific delivery for in vivo testing, we conjugated the most potent saV2-9 RNA molecule with the prostate-specific membrane antigen (PSMA)-targeting aptamer A10-3.2. The conjugates successful increased DPYSL3v2 gene expression in PSMA-positive but not PSMA-negative prostate cancer cells. In nude mice bearing orthotopic xenograft of prostate cancer, a 10-day consecutive treatment with the saV2-9 conjugates significantly suppress distal metastasis compared to the control saRNAs. Analysis of xenograft tissues revealed that DPYSL3v2 expression was largely increased in saV2-9 conjugate-treated group compared to the control group. In conclusion, DPYSL3v2 promoter-targeted saRNA molecules might be used as an adjunctive therapy to suppress prostate cancer metastasis.

Nanomicellar TGX221 blocks xenograft tumor growth of prostate cancer in nude mice.

BACKGROUND: Combination of androgen ablation along with early detection and surgery has made prostate cancer highly treatable at the initial stage. However, this cancer remains the second leading cause of cancer death among American men due to castration-resistant progression, suggesting that novel therapeutic agents are urgently needed for this life-threatening condition. Phosphatidylinositol 3-kinase p110ß is a major cellular signaling molecule and has been identified as a critical factor in prostate cancer progression. In a recent report, we established a nanomicelle-based strategy to deliver p110ß-specific inhibitor TGX221 to prostate cancer cells by conjugating the surface of nanomicelles with a RNA aptamer against prostate specific membrane antigen (PSMA) present in all clinical prostate cancers. In this study, we tested this nanomicellar TGX221 for its in vivo anti-tumor effect in mouse xenograft models. METHODS: Prostate cancer cell lines LAPC-4, LNCaP, C4-2 and 22RV1 were used to establish subcutaneous xenograft tumors in nude mice. Paraffin sections from xenograft tumor specimens were used in immunohistochemistry assays to detect AKT phosphorylation, cell proliferation marker Ki67 and proliferating cell nuclear antigen (PCNA), as well as 5-bromo-2-deoxyuridine (BrdU) incorporation. Quantitative PCR assay was conducted to determine prostate-specific antigen (PSA) gene expression in xenograft tumors. RESULTS: Although systemic delivery of unconjugated TGX221 significantly reduced xenograft tumor growth in nude mice compared to solvent control, the nanomicellar TGX221 conjugates completely blocked tumor growth of xenografts derived from multiple prostate cancer cell lines. Further analyses revealed that AKT phosphorylation and cell proliferation indexes were dramatically reduced in xenograft tumors received nanomicellar TGX221 compared to xenograft tumors received unconjugated TGX221 treatment. There was no noticeable side effect by gross observation or at microscopic level of organ tissue section. CONCLUSION: These data strongly suggest that prostate cancer cell-targeted nanomicellar TGX221 is an effective anti-cancer agent for prostate cancer.

PI-3 kinase p110ß: a therapeutic target in advanced prostate cancers.

Prostate cancers in the castration-resistant stage are life-threatening because they are not curable in clinic. The novel androgen receptor inhibitor Xandi (Enzalutamide) and the new CYP17 inhibitor Zytiga (Abiraterone) prolonged patient survival only a few months in advanced prostate cancers. Therefore, novel therapeutic agents for advanced prostate cancers are urgently needed. PI-3 kinases are major intracellular signaling molecules that regulate multiple signal pathways related to cellular metabolism, cytokinesis, growth and survival. Accumulating evidence in the literature indicates that some isoforms of this kinase family are oncogenic and abnormally expressed in various human cancers, including prostate cancers. Recent extensive studies from our group and others showed that PI-3 kinase p110ß is aberrantly overexpressed in advanced prostate cancers and is critical for prostate cancer development and progression as demonstrated in cell-based and animal models. Importantly, novel p110ß-specific inhibitors have been developed and are currently been testing in clinical trials. In this article, we will briefly summarize recent developments in this regard.