Human papillomaviruses (HPV) activate a number of host factors to control their differentiation-dependent life cycles. The transcription factor signal transducer and activator of transcription (STAT)-3 is important for cell cycle progression and cell survival in response to cytokines and growth factors. STAT3 requires phosphorylation on Ser727, in addition to phosphorylation on Tyr705 to be transcriptionally active. In this study, we show that STAT3 is essential for the HPV life cycle in undifferentiated and differentiated keratinocytes. Primary human keratinocytes containing high-risk HPV18 genomes display enhanced STAT3 phosphorylation compared to normal keratinocytes. Expression of the E6 oncoprotein is sufficient to induce the dual phosphorylation of STAT3 at Ser727 and Tyr705 by a mechanism requiring Janus kinases and members of the MAPK family. E6-mediated activation of STAT3 induces the transcription of STAT3 responsive genes including cyclin D1 and Bcl-xL. Silencing of STAT3 protein expression by siRNA or inhibition of STAT3 activation by small molecule inhibitors, or by expression of dominant negative STAT3 phosphorylation site mutants, results in blockade of cell cycle progression. Loss of active STAT3 impairs HPV gene expression and prevents episome maintenance in undifferentiated keratinocytes and upon differentiation, lack of active STAT3 abolishes virus genome amplification and late gene expression. Organotypic raft cultures of HPV18 containing keratinocytes expressing a phosphorylation site STAT3 mutant display a profound reduction in suprabasal hyperplasia, which correlates with a loss of cyclin B1 expression and increased differentiation. Finally, increased STAT3 expression and phosphorylation is observed in HPV positive cervical disease biopsies compared to control samples, highlighting a role for STAT3 activation in cervical carcinogenesis. In summary, our data provides evidence of a critical role for STAT3 in the HPV18 life cycle.
Background The current biomarkers alpha-fetoprotein (AFP) and human chorionic gonadotropin (HCG) have limited sensitivity/specificity for diagnosing malignant germ cell tumors (GCTs) and “marker-negative” patients require histological confirmation for diagnosis. However, GCTs at intracranial sites are surgically relatively inaccessible and biopsy carries risks. MicroRNAs from the miR-371~373 and miR-302/367 clusters are over-expressed in all malignant GCTs and, in particular, miR-371a-3p shows elevated serum levels at diagnosis for testicular disease. Methods Using our robust preamplified qRT-PCR methodology, we quantified miR-371a-3p levels in serum and cerebrospinal fluid (CSF) in a series of 4 representative clinical cases, 3 with intracranial malignant GCT and 1 with Langerhans cell histiocytosis (LCH), compared with appropriate control cases. Results Serum and/or CSF miR-371a-3p levels distinguished those with intracranial malignant GCTs from LCH and, if known in real time, could have helped clinical management. The benefits would have included (1) the only confirmatory evidence of an intracranial malignant GCT in 1 case, supporting clinical decision making; (2) early detection of intracranial malignant GCT in another, where an elevated CSF miR-371a-3p level preceded the histologically confirmed diagnosis by 2 years; and (3) confirmation of an intracranial malignant GCT relapse with an elevated serum miR-371a-3p level, where serum and CSF AFP and HCG levels were below thresholds for such a diagnosis. Conclusions This series highlights the potential for microRNA quantification to assist the noninvasive diagnosis, prognostication, and management for patients with intracranial malignant GCTs. Serum and CSF should be collected routinely as part of future studies to facilitate the extension of these findings to larger patient cohorts.
Quantifying circulating nucleic acids is an important new approach to cancer diagnosis/monitoring. We compared the suitability of serum versus plasma for measuring miRNAs using qRT-PCR and assessed how preanalytic variables that can affect circulating tumor DNA (ctDNA) quantification in plasma also influence miRNA levels. Across 62 blood-derived specimens, plasma samples in EDTA, Streck-DNA, and Streck-RNA tubes showed significantly higher values for multiple housekeeping miRNAs, compared with serum samples. For the EDTA-plasma tubes, this difference was only seen when including the high-speed centrifugation protocol used to optimize ctDNA extraction. In plasma samples derived from blood stored at room temperature for up to 14 days (conditions that typically apply to samples processed for biobanking), levels of endogenous housekeeping miRNAs gradually increased, in parallel with the hemolysis marker hsa-miR-451a, consistent with release from blood cells/platelets. It was necessary to normalize levels of the housekeeping miRNAs to those of hsa-miR-451a, to obtain the stable values needed for referencing test miRNA levels. Our data indicate that plasma samples prepared for ctDNA extraction are suboptimal for miRNA quantification and require the incorporation of multiple data normalization steps. For prospective studies designed to measure both miRNAs and ctDNA, the most suitable approach would be to obtain both serum (for miRNAs) and plasma (for ctDNA). If only plasma can be collected, we recommend an initial low-speed centrifugation step, followed by aliquoting the supernatant into parallel samples, one for direct miRNA quantification, and the other for a further high-speed centrifugation step to optimize ctDNA retrieval. These recommendations will help "future-proof" clinical studies in which quantification of circulating miRNAs is a component. .
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Introduction and objective Conventional serum tumor markers (STMs) for testicular germ cell tumors (GCTs) offer limited performance with particularly poor sensitivity in cases of minimal residual disease and pure seminoma. While growing evidence has indicated miR‐371a‐3p to be a superior biomarker, its utility in detecting pure seminoma at recurrence has not been extensively explored. This study's objective was to explore miR‐371a‐3p's utility in detecting metastatic pure seminoma at retroperitoneal lymph node dissection (RPLND). Methods RNA was isolated from patient serum samples collected pre‐RPLND. Fifteen patients were assigned to our ‘benign’ (n = 6) or ‘seminoma’ (n = 9) group based on pathological confirmation of viable seminoma. Five of the patients received chemotherapy before RPLND (PC‐RPLND), and 10 were chemotherapy naïve. MiR‐371a‐3p expression was quantified via RT‐quantitative polymerase chain reaction. The Cq values were statistically evaluated to obtain performance measurements. Results Median relative expression of miR‐371a‐3p was higher in the Seminoma group than the Benign, but this difference was not statistically significant (Rq = 3705 and 241, respectively, p = 0.2844). Of the 10 chemotherapy naïve patients, nine had viable seminoma at RPLND, and seven had elevated miR‐371a‐3p expression. Among the five postchemotherapy (PC) patients, zero had viable GCT at RPLND, and two had elevated miR‐371a‐3p expression. The primary RPLND group presented 78% sensitivity and 100% specificity. Specificity in the PC‐RPLND group was 60%. An optimal Rq threshold of 28.62 was determined by Youden's J statistic, yielding 78% sensitivity and 67% specificity. Receiver operating characteristic analysis provided an AUC of 0.704 (95% CI: 0.43–0.98, p = 0.1949). Despite modest performance, miR‐371a‐3p exhibited improved sensitivity and specificity compared with conventional STMs. Conclusions MiR‐371a‐3p outperformed STMs in the primary RPLND settings. However, miR‐371a‐3p was not a robust predictor of pathology in the PC setting. These results suggest that pure seminoma at RPLND is a clinical context, wherein the miRNA assay may require further refinement.
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