Black phosphorus (BP)-based nanomaterials have distinguished advantages and potential applications in various biomedical fields. However, their biological effects in physiological systems remain largely unexplored. Here, we systematically revealed a reactive oxygen species (ROS)-mediated mechanism for the selective killing of cancer cells by BP-based nanosheets. The treatment with BP-based materials can induce higher levels of ROS in cancer cells than in normal cells, leading to significant changes in the cytoskeleton, cell cycle arrest, DNA damage, and apoptosis in tumor cell lines. We revealed that the decreased superoxide dismutase activity by lipid peroxides could be an essential mechanism of the selectively higher ROS generation induced by BP-based nanosheets in cancer cells. In addition, the selective killing effect only occurred within a certain dosage range (named “SK range” in this study). Once exceeding the SK range, BP-based materials could also induce a high ROS production in normal tissues, leading to detectable DNA damage and pathological characteristics in normal organs and raising safety concerns. These findings not only shed light on a new mechanism for the selective killing of cancer cells by BP-based materials but also provide deep insights into the safe use of BP-based therapies.
BackgroundMany applications of CRISPR/Cas9-mediated genome editing require Cas9-induced non-homologous end joining (NHEJ), which was thought to be error prone. However, with directly ligatable ends, Cas9-induced DNA double strand breaks may be repaired preferentially by accurate NHEJ.ResultsIn the repair of two adjacent double strand breaks induced by paired Cas9-gRNAs at 71 genome sites, accurate NHEJ accounts for about 50% of NHEJ events. This paired Cas9-gRNA approach underestimates the level of accurate NHEJ due to frequent + 1 templated insertions, which can be avoided by the predefined Watson/Crick orientation of protospacer adjacent motifs (PAMs). The paired Cas9-gRNA strategy also provides a flexible, reporter-less approach for analyzing both accurate and mutagenic NHEJ in cells and in vivo, and it has been validated in cells deficient for XRCC4 and in mouse liver. Due to high frequencies of precise deletions of defined “3n”-, “3n + 1”-, or “3n + 2”-bp length, accurate NHEJ is used to improve the efficiency and homogeneity of gene knockouts and targeted in-frame deletions. Compared to “3n + 1”-bp, “3n + 2”-bp can overcome + 1 templated insertions to increase the frequency of out-of-frame mutations. By applying paired Cas9-gRNAs to edit MDC1 and key 53BP1 domains, we are able to generate predicted, precise deletions for functional analysis. Lastly, a Plk3 inhibitor promotes NHEJ with bias towards accurate NHEJ, providing a chemical approach to improve genome editing requiring precise deletions.ConclusionsNHEJ is inherently accurate in repair of Cas9-induced DNA double strand breaks and can be harnessed to improve CRISPR/Cas9 genome editing requiring precise deletion of a defined length.Electronic supplementary materialThe online version of this article (10.1186/s13059-018-1518-x) contains supplementary material, which is available to authorized users.
Coronavirus disease 2019 (COVID-19) caused by severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) is a severe and rapidly evolving epidemic. Now, although a few drugs and vaccines have been proved for its treatment and prevention, little systematic comments are made to explain its susceptibility to humans. A few scattered studies used bioinformatics methods to explore the role of microRNA (miRNA) in COVID-19 infection. Combining these timely reports and previous studies about virus and miRNA, we comb through the available clues and seemingly make the perspective reasonable that the COVID-19 cleverly exploits the interplay between the small miRNA and other biomolecules to avoid being effectively recognized and attacked from host immune protection as well to deactivate functional genes that are crucial for immune system. In detail, SARS-CoV-2 can be regarded as a sponge to adsorb host immune-related miRNA, which forces host fall into dysfunction status of immune system. Besides, SARS-CoV-2 encodes its own miRNAs, which can enter host cell and are not perceived by the host’s immune system, subsequently targeting host function genes to cause illnesses. Therefore, this article presents a reasonable viewpoint that the miRNA-based interplays between the host and SARS-CoV-2 may be the primary cause that SARS-CoV-2 accesses and attacks the host cells.
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