Placental microRNAs (miRNAs) regulate the placental transcriptome and play a pathological role in preeclampsia (PE), a hypertensive disorder of pregnancy. Three PE rodent model studies explored the role of placental miRNAs, miR-210, miR-126, and miR-148/152 respectively, by examining expression of the miRNAs, their inducers, and potential gene targets. This review evaluates the role of miR-210, miR-126, and miR-148/152 in PE by comparing findings from the three rodent model studies with in vitro studies, other animal models, and preeclamptic patients to provide comprehensive insight into genetic components and pathological processes in the placenta contributing to PE. The majority of studies demonstrate miR-210 is upregulated in PE in part driven by HIF-1α and NF-κBp50, stimulated by hypoxia and/or immune-mediated processes. Elevated miR-210 may contribute to PE via inhibiting anti-inflammatory Th2-cytokines. Studies report an up- and downregulation of miR-126, arguably reflecting differences in expression between cell types and its multifunctional capacity. MiR-126 may play a pro-angiogenic role by mediating the PI3K-Akt pathway. Most studies report miR-148/152 family members are upregulated in PE. Evidence suggests they may inhibit DNA methylation of genes involved in metabolic and inflammatory pathways. Given the genetic heterogeneity of PE, it is unlikely that a single placental miRNA is a suitable therapeutic target for all patients. Investigating miRNAs in PE subtypes in patients and animal models may represent a more appropriate approach going forward. Developing methods for targeting placental miRNAs and specific placental cell types remains crucial for research seeking to target placental miRNAs as a novel treatment for PE.
Ultrasound (US) and microbubble (MB) gene delivery has attracted growing interest as a clinically applicable gene therapy (GT). Though preclinical studies have investigated the system in various tissues, there is limited research in targeting the placenta. This is a potential therapeutic strategy for preeclampsia (PE), which has an underlying genetic basis and ineffective management strategies. Differentially expressed placental microRNAs (miRNAs) in PE may represent suitable targets for GT. Microbubbles (SonoVue) and plasmid (pGL3 or pGL4.13) were administered systemically to CD1 mice, followed by exposure of the heart to US (B-mode, H14, 1.8 M.I., 1cm focal depth, 2 minutes), using Siemens Acuson Sequoia-512 system and 15L8 probe. Luciferase assays were performed to evaluate gene transfection. Significantly differentially expressed placental miRNAs in PE patients were identified as candidate miRNAs based on detection by ≥3 screening studies. Expression of candidate miRNAs was measured by qRT-PCR in PE rat model placentas. In trial 1, low levels of luciferase activity were detected in the heart of treatment mouse 1, 2 and 3. In trial 2, luciferase activity was evident in the atria of treatment mouse 2. In trial 3, higher luciferase activity was detected in the ventricles of the treatment mouse and activity was also detected in the atria. The literature review identified eight candidate miRNAs. MiR-223 (1.46-fold increase) and miR-181a (0.81-fold decrease) were significantly differentially expressed in PE rat model placentas. MiR-223 and miR-181a may represent targets for US and MB gene delivery. Future studies will apply the US and MB gene delivery protocol for translation to targeting the placenta in our PE rodent model.
Ultrasound (US) and microbubble (MB) gene delivery has attracted growing interest as a clinically applicable gene therapy (GT). Though preclinical studies have investigated the system in various tissues, there is limited research in targeting the placenta. This is a potential therapeutic strategy for preeclampsia (PE), which has an underlying genetic basis and ineffective management strategies. Differentially expressed placental microRNAs (miRNAs) in PE may represent suitable targets for GT. Microbubbles (SonoVue) and plasmid (pGL3 or pGL4.13) were administered systemically to CD1 mice, followed by exposure of the heart to US (B-mode, H14, 1.8 M.I., 1cm focal depth, 2 minutes), using Siemens Acuson Sequoia-512 system and 15L8 probe. Luciferase assays were performed to evaluate gene transfection. Significantly differentially expressed placental miRNAs in PE patients were identified as candidate miRNAs based on detection by ≥3 screening studies. Expression of candidate miRNAs was measured by qRT-PCR in PE rat model placentas. In trial 1, low levels of luciferase activity were detected in the heart of treatment mouse 1, 2 and 3. In trial 2, luciferase activity was evident in the atria of treatment mouse 2. In trial 3, higher luciferase activity was detected in the ventricles of the treatment mouse and activity was also detected in the atria. The literature review identified eight candidate miRNAs. MiR-223 (1.46-fold increase) and miR-181a (0.81-fold decrease) were significantly differentially expressed in PE rat model placentas. MiR-223 and miR-181a may represent targets for US and MB gene delivery. Future studies will apply the US and MB gene delivery protocol for translation to targeting the placenta in our PE rodent model.
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