The atomic and electronic properties of black phosphorus (BP), which has been recently shown to have potential application as anode material for lithium ion batteries, are studied via ab initio calculations. The calculations reveal that the interlayer interaction in BP is Van der Waals Keesom force, which is critical to the formation of the layered structure. Interestingly, we also found that the small band gap of bulk BP (0.19 eV) when compared with that of single layer BP (0.75 eV) is partly because of the interlayer Van der Waals interaction in BP. The change in a materials band structure because of Van der Waals interaction is rarely reported in literature.
In vitro 3D growth of tumors is a new cell culture model that more closely mimics the features of the in vivo environment and is being used increasingly in the field of biological and medical research. It has been demonstrated that cancer cells cultured in 3D matrices are more radio-resistant compared with cells in monolayers. However, the mechanisms causing this difference remain unclear. Here we show that cancer cells cultured in a 3D microenvironment demonstrated an increase in cells with stem cell properties. This was confirmed by the finding that cells in 3D cultures upregulated the gene and protein expression of the stem cell reprogramming factors such as OCT4, SOX2, NANOG, LIN28 and miR-302a, compared with cells in monolayers. Moreover, the expression of β-catenin, a regulating molecule of reprogramming factors, also increased in 3D-grown cancer cells. These findings suggest that cancer cells were reprogrammed to become stem cell–like cancer cells in a 3D growth culture microenvironment. Since cancer stem cell–like cells demonstrate an increased radio-resistance and chemo-resistance, our results offer a new perspective as to why. Our findings shed new light on understanding the features of the 3D growth cell model and its application in basic research into clinical radiotherapy and medicine.
MicroRNAs (miRNAs) are emerging as vital biomarkers since their abnormal expression is associated with various disease types including cancer. Therefore, it is essential to develop a sensitive and specific platform to monitor the dynamic expression of miRNAs for early clinical diagnosis and treatment. In this study, we designed a functionalized polydopamine (PDA)-based theranostic nanoprobe for efficient detection of miRNA-21 and
in vivo
synergistic cancer therapy. PDA was modified with polyethylene glycol (PEG) and the obtained PDA-PEG nanoparticles showed good stability in different solutions. PDA-PEG nanoparticles were loaded with fluorescein isothiocyanate (FITC)-labeled hairpin DNA (hpDNA) and an anticancer drug doxorubicin (DOX). In the absence of miRNA-21, PDA effectively quenched the fluorescence of FITC-labeled hpDNA. The presence of miRNA-21 specifically recognized hpDNA and induced the dissociation of hpDNA from PDA-PEG and subsequently recovered the fluorescence signals. Upon cellular uptake of these nanoprobes, a dose-dependent fluorescence activation and synergetic cytotoxic effect were observed due to the release of DOX and inhibition of miRNA-21 function. Furthermore, PDA-PEG-DOX-hpDNA nanoparticles can afford long-term monitoring of miRNA-21 and combined therapeutic efficacy in the nude mice bearing 4T1 tumors. Our results demonstrate the capability of PDA-PEG-DOX-hpDNA as a theranostic nanoprobe for continuously tracking of miRNAs and synergetic cancer therapy.
Radiation-induced genomic instability plays a vital role in carcinogenesis. Bod1 is required for proper chromosome biorientation, and Bod1 depletion increases premature chromatid separation. MiR-142-3p influences cell cycle progression and inhibits proliferation and invasion in cervical carcinoma cells. We found that radiation induced premature chromatid separation and altered miR-142-3p and Bod1 expression in 786-O and A549 cells. Overexpression of miR-142-3p increased premature chromatid separation and G2/M cell cycle arrest in 786-O cells by suppressing Bod1 expression. We also found that either overexpression of miR-142-3p or knockdown of Bod1 sensitized 786-O and A549 cells to X-ray radiation. Overexpression of Bod1 inhibited radiation- and miR-142-3p-induced premature chromatid separation and increased resistance to radiation in 786-O and A549 cells. Taken together, these results suggest that radiation alters miR-142-3p and Bod1 expression in carcinoma cells, and thus contributes to early stages of radiation-induced genomic instability. Combining ionizing radiation with epigenetic regulation may help improve cancer therapies.
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