Recently, reflectionless or low‐reflection surfaces made of subwavelength structures have been of broad interest in practical engineering. Here, a single‐layer terahertz metasurface is proposed to produce ultralow reflections across a broad‐frequency spectrum and wide incidence angles by controlling the reflection phases of subwavelength structures. To enable full control of the phase range in a continuous band, a combination of two different subwavelength elements are employed, both of which exhibit weak interactions with the incident terahertz waves, thereby showing high local reflectivities near the operating frequency. An optimization method is utilized to determine the array pattern with the minimum overall reflections under the illumination of plane waves. Both numerical simulations and experimental results demonstrate ultralow reflections of terahertz waves by the metasurface over a broad frequency band and wide incidence angles. By using the proposed metasurface, the far‐field scattering patterns of metallic objects can be efficiently controlled, which opens up a new route for low‐reflection surface designs in the terahertz spectrum.
Syncytin-1 is a protein coded by a human endogenous retrovirus (HERV) gene of the HERV-W family (HERVWE1). Syncytin- 1 mediates formation of syncytiotrophoblasts through fusion of cytotrophoblasts, a hallmark of terminal differentiation of placental trophoblast linage. Syncytin-1 also possesses nonfusogenic functions and regulates cell cycle progression. While decreased syncytin-1 expression and syncytium deficiency are considered important pathological changes in preeclampsia, the molecular mechanism(s) underlying syncytin-1 downregulation remains unclear. In this study, we confirmed that expression levels of syncytin-1 mRNA and protein were significantly lower in preeclamptic placentas compared to normal controls. Human chorionic somatomammotropin expression, a marker for syncytium function, was also decreased in preeclamptic placentas. The mRNA levels of ASCT2, the syncytin-1 receptor involved in cell fusion process, and GCMa, a transcriptional factor known to regulate syncytin-1 expression, were not significantly altered. Methylation in the 5'LTR of syncytin-1 promoter was quantified by COBRA, methylation-specific PCR, and DNA sequencing. Results from all three assays indicated significantly hypermethylated syncytin-1 promoter in preeclamptic placentas compared to normal controls. Methylation levels were inversely correlated with syncytin-1 mRNA levels, suggesting that hypermethylation may lead to syncytin-1 downregulation. Further experiments indicated that DNMT1 and DNMT3B3 mRNA and protein levels were increased in preeclamptic placentas, suggesting that higher DNA methyltransferase activity may contribute to the hypermethylation of syncytin-1 in preeclamptic placentas. These results indicated that aberrant hypermethylation is involved in downregulation of syncytin-1, and epigenetic alterations may play a significant role in the development of preeclampsia.
Low‐scattering metasurfaces in the terahertz region can benefit a number of applications such as imaging, radar, and novel light sources. Such metasurfaces can efficiently suppress specular reflection and diffuse the energy that comes back without preferred direction. However, the accurate bandwidth control of low‐scattering metasurfaces is still a main issue to be investigated. To solve the problem, here a new strategy to realize the low‐scattering metasurfaces with desired bandwidths is proposed. Different from the earlier work, the current design is carried out within a broad spectrum instead of at a single frequency, giving rise to the arbitrarily desired bandwidth. Three basic elements are proposed to construct the new metasurface, and the diffuse reflection feature can be attributed to their destructive interferences with the change of operating frequency. The intrinsic loss of the meta‐atoms is also taken into account to make the theoretical model more accurate in the practical design. Excellent scattering‐suppression features are observed in the predefined frequency bands in both simulated and experimental results, which have very good agreements with the theoretical predictions.
Epithelial stromal cells represent a major cellular component of human uterine endometrium that is subject to tight hormonal regulation. Through cell-cell contacts and/or paracrine mechanisms, stromal cells play a significant role in the malignant transformation of epithelial cells. We isolated stromal cells from normal human endometrium and investigated the morphological and transcriptional changes induced by estrogen, progesterone and tamoxifen. We demonstrated that stromal cells express appreciable levels of estrogen and progesterone receptors and undergo different morphological changes upon hormonal stimulation. Microarray analysis indicated that both estrogen and progesterone induced dramatic alterations in a variety of genes associated with cell structure, transcription, cell cycle, and signaling. However, divergent patterns of changes, and in some genes opposite effects, were observed for the two hormones. A large number of genes are identified as novel targets for hormonal regulation. These hormone-responsive genes may be involved in normal uterine function and the development of endometrial malignancies.
Syncytin-1 plays a critical role in the maintenance of normal pregnancy by mediating the formation of syncytiotrophoblasts through a fosugenic action. Encoded by the human endogenous retrovirus envelope gene HERV-W, syncytin-1 trophoblast-specific expression is controlled by epigenetic mechanisms. In non-placental tissues, the syncytin-1 gene is suppressed by hypermethylation in the LTR promoter region. Hypomethylated and activated syncytin-1 gene is found in placental trophoblast lineages and malignant cells. We here demonstrate that while syncytin-1 gene remains silenced in the eutopic endometrium from endometriotic patients, syncytin-1 mRNA and protein are detected in ectopic, endometriotic lesions; particularly the endometrioid glandular endothelial cells. LINE-1 COBRA assay and immunohistochemistry using the 5-MC-specific antibody did not detect any changes in global DNA methylation in the endometriotic tissues. However, results from COBRA and bisulfite sequencing indicated that the LTR region of the syncytin-1 promoter is hypomethylated in endometriotic tissues, highlighting the significance of DNA demethylation in syncytin-1 gene activation. Analysis of DNA methyltransferase 3B (DNMT3B) mRNA levels revealed that DNMT3B3, an isoform carrying methyltransferase activity, is downregulated; whereas DNMT3B7, the isoform without enzymatic activity, is upregulated in the endometriotic tissues, pointing to positive and negative regulatory functions, respectively, of these isoforms on syncytin-1 methylation. These results have provided the first evidence supporting the involvement of epigenetic mechanisms for syncytin-1 upregulation in endometriotic tissues. Considering recent findings on the nonfusogenic activity of syncytin-1, its expression in endometriotic tissues suggests that this multifunctional protein may be implicated in the pathogenesis and/or progression of endometriosis.
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