MiR-93/miR-375: Diagnostic Potential, Aggressiveness Correlation and Common Target Genes in Prostate Cancer

Ciszkowicz, Ewa; Porzycki, Paweł; Semik, Małgorzata; Kaznowska, Ewa; Tyrka, Mirosław

doi:10.3390/ijms21165667

Cited by 14 publications

(15 citation statements)

References 93 publications

(97 reference statements)

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“…However, several miRNAs, such as miR-141, miR-375, and miR-130b, lost interest as biomarkers when performing expression analysis in the present study because there were no differences among PC risk or even prognosis. Nevertheless, when looking in literature, these are among the most highlighted miRNAs as suitable biomarkers in urine, for PC diagnosis and progression [19,21]; in plasma, for time to progression of metastatic castration-resistant PC or biomarker screening [20,23,24,59]; or even associated with an increased risk of biochemical recurrence [60]. By contrast, when studying them in the present bioinformatics analyses, these three miRNAs (miR-141, miR-375, and miR-130b) completely lost total statistical power (Figures 3 and 4).…”

Section: Discussionmentioning

confidence: 99%

“…miR-375 has been included as one of the classical miRNAs' biomarkers in PC. It has importance in several points of the disease, such as clinical T-stage and bone metastasis, distinguishing between PC patients versus controls, and even differentiating between benign prostatic hyperplasia (BPH) in urinary and serum exosomes [19][20][21]. This miRNA has been included as one of the main points for regulating proliferation, metastasis, and EMT in PC, and it has also been included with a significant down-regulation after radical prostatectomy in urine extracellular vesicles (EVs), clarified urine, and blood plasma [22].…”

Section: Introductionmentioning

confidence: 99%

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Identification of MicroRNAs as Viable Aggressiveness Biomarkers for Prostate Cancer

et al. 2021

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MiRNAs play a relevant role in PC (prostate cancer) by the regulation in the expression of several pathways’ AR (androgen receptor), cellular cycle, apoptosis, MET (mesenchymal epithelium transition), or metastasis. Here, we report the role of several miRNAs’ expression patterns, such as miR-miR-93-5p, miR-23c, miR-210-3p, miR-221-3p, miR-592, miR-141, miR-375, and miR-130b, with relevance in processes like cell proliferation and MET. Using Trizol® extraction protocol and TaqMan™ specific probes for amplification, we performed miRNAs’ analysis of 159 PC fresh tissues and 60 plasmas from peripheral blood samples. We had clinical data from all samples including PSA, Gleason, TNM, and D’Amico risk. Moreover, a bioinformatic analysis in TCGA (The Cancer Genome Atlas) was included to analyze the effect of the most relevant miRNAs according to aggressiveness in an extensive cohort (n = 531). We found that miR-210-3p, miR-23c, miR-592, and miR-93-5p are the most suitable biomarkers for PC aggressiveness and diagnosis, respectively. In fact, according with our results, miR93-5p seems the most promising non-invasive biomarker for PC. To sum up, miR-210-3p, miR-23c, miR-592, and miR93-5p miRNAs are suggested to be potential biomarkers for PC risk stratification that could be included in non-invasive strategies such as liquid biopsy in precision medicine for PC management.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Identification of MicroRNAs as Viable Aggressiveness Biomarkers for Prostate Cancer

et al. 2021

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“…In contrast, its overall expression (defined as both epithelial and stromal expression) strongly relates to Gleason grade (P=0.001) (105). It was recently shown that plasma levels of miR-141-3p and miR-375-3p might predict time to progression in mCRPC patients treated with docetaxel or abiraterone; their high baseline levels were significantly associated with shorter overall survival (OS) in the abiraterone and in docetaxel treated patients (106)(107)(108).…”

Section: General Epigenetic Landscape In Prostate Cancer and Micro-rnasmentioning

confidence: 99%

Genetics of Prostate Carcinoma

Krušlin

Škara

Vodopić

et al. 2021

ama

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The aim of this review is to provide a brief overview of some current approaches regarding diagnostics, pathologic features, treatment, and genetics of prostate carcinoma (PCa). Prostate carcinoma is the most common visceral tumor and the second most common cancer-related cause of death in males. Clinical outcomes for patients with localized prostate cancer are excellent, but despite advances in prostate cancer treatments, castrate-resistant prostate cancer and metastatic prostate cancer patients have a poor prognosis. Advanced large-scale genomic studies revealed a large number of genetic alterations in prostate cancer. The meaning of these alterations needs to be validated in the specific prostate cancer molecular subtype context. Along these lines, there is a critical need for establishing genetically engineered mouse models, which would include speckle type BTB/POZ protein and isocitrate Dehydrogenase (NADP (+)) 1 mutant, as well as androgen receptor neuroendocrine subtypes of prostate cancer. Another urgent need is developing highly metastatic prostate cancer models, as only up to 17% of available models dis- play bone metastases and exhibit a less typical neuroendocrine prostate cancer or sarcomatoid carcinoma. Moreover, androgen deprivation and relapse should be mimicked in the genetically engineered mouse models, as androgen independence may yield a better model for metastatic castrate-resistant prostate cancer. The development of such refined animal models should be guid- ed by comparative genomics of primary versus corresponding metastatic tumors. Such an approach will have the potential to illuminate the key genetic events associated with specific molecular prostate cancer subsets and indicate directions for effective therapy.Conclusion. Despite excellent results in the treatment of localized prostatic carcinoma, castrate-resistant prostate can- cer and metastatic prostate cancer have a poor prognosis. Advanced large-scale genomic studies revealed a large number of ge- netic alterations in PCa. Experimental models of prostate carcinoma in genetically modified mice could provide new data about the genetic changes in such cancers and help in developing better animal models for treatment resistant prostate carcinomas.

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“…• 12 of 42 with an  in malignancy [233]   in PCa vs BPH [263]   in PCa [264] [265]   in PCa and metastases [266]   viability, migration, invasion [264]  overrides radiation-induced cell cycle arrest [267]  associated with disease recurrence [266] --  in PCa [199]   in patients with LN metastases [269]  promotes PCa progression [270,271]   expression predicts poor survival [272]  blood: BPH vs PCa [208]  seminal plasma: disease aggressiveness [   favors progression and self-renewal [129]   correlates with early clinical failure [286]  urine: cancer cell -macrophage signalling [287]  urine: PCa vs healthy [288]  negative regulation by lncRNA TTTY15 [289]  suppresses AR via Myc [290] in NEPC tissues [194] • 12 of 42 with an  in malignancy [233]   in PCa vs BPH [263]   in PCa [264] [265]   in PCa and metastases [266]   viability, migration, invasion [264]  overrides radiation-induced cell cycle arrest [267]  associated with disease recurrence [266] --  in PCa [199]   in patients with LN metastases [269]  promotes PCa progression [270,271]   expression predicts poor survival [272]  blood: BPH vs PCa [208]  seminal plasma: disease aggressiveness [273]  plasma: disease prediction [274]  serum: PCa diagnosis [275] -  in PCa [199]   in advanced PCa [260]   in patients with LN metastases …”

Section: Mirnas In the Regulation Of Ned And Prostate Cancer Progressionmentioning

confidence: 99%

“…  in PCa [199]   in patients with LN metastases [269]  promotes PCa progression [270,271]   expression predicts poor survival [272]  blood: BPH vs PCa [208]  seminal plasma: disease…”

Section: Mirnas In the Regulation Of Ned And Prostate Cancer Progressionmentioning

confidence: 99%

Regulation of Neuroendocrine-like Differentiation in Prostate Cancer by Non-Coding RNAs

Slabáková

Kahounová

Procházková

et al. 2021

ncRNA

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Neuroendocrine prostate cancer (NEPC) represents a variant of prostate cancer that occurs in response to treatment resistance or, to a much lesser extent, de novo. Unravelling the molecular mechanisms behind transdifferentiation of cancer cells to neuroendocrine-like cancer cells is essential for development of new treatment opportunities. This review focuses on summarizing the role of small molecules, predominantly microRNAs, in this phenomenon. A published literature search was performed to identify microRNAs, which are reported and experimentally validated to modulate neuroendocrine markers and/or regulators and to affect the complex neuroendocrine phenotype. Next, available patients’ expression datasets were surveyed to identify deregulated microRNAs, and their effect on NEPC and prostate cancer progression is summarized. Finally, possibilities of miRNA detection and quantification in body fluids of prostate cancer patients and their possible use as liquid biopsy in prostate cancer monitoring are discussed. All the addressed clinical and experimental contexts point to an association of NEPC with upregulation of miR-375 and downregulation of miR-34a and miR-19b-3p. Together, this review provides an overview of different roles of non-coding RNAs in the emergence of neuroendocrine prostate cancer.

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MiR-93/miR-375: Diagnostic Potential, Aggressiveness Correlation and Common Target Genes in Prostate Cancer

Cited by 14 publications

References 93 publications

Identification of MicroRNAs as Viable Aggressiveness Biomarkers for Prostate Cancer

Identification of MicroRNAs as Viable Aggressiveness Biomarkers for Prostate Cancer

Genetics of Prostate Carcinoma

Regulation of Neuroendocrine-like Differentiation in Prostate Cancer by Non-Coding RNAs

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