Abstract Four new PKS‐NRPS‐derived macrolide lactams with three unique ring fusion types were discovered from the Arctic sponge associated actinomycete Streptomyces somaliensis 1107 using a genome mining strategy. Their structures were elucidated by a combination of MS, NMR spectroscopic analysis, and single‐crystal X‐ray diffraction. Biosynthetically, a novel gene cluster sml consisting of three polyketide synthases and one hybrid polyketide synthase‐nonribosomal peptide synthetase together with cytochrome P450s and flavin‐containing monooxygenases and oxidoreductases was demonstrated to assemble the unique skeleton. Pharmacological studies revealed that compound 1 displayed a potent anti‐inflammatory effect without cytotoxicity. It inhibited IL‐6 and TNF‐α release in the serum of LPS‐stimulated RAW264.7 macrophage cells with IC 50 values of 5.76 and 0.18 μM, respectively, and modulated the MAPK pathway. Moreover, compound 1 alleviated LPS‐induced systemic inflammation in our transgenic fluorescent zebrafish model.
A synergistic bimetallic enzyme mimetic catalyst, three-dimensional (3D) graphene/Fe3O4–AuNPs, was successfully fabricated which exhibited flexibly switchable peroxidase-like activity. Compared to the traditional 2D graphene-based monometallic composite, the introduced 3D structure, which was induced by the addition of glutamic acid, and bimetallic anchoring approach dramatically improved the catalytic activity, as well as the catalysis velocity and its affinity for substrate. Herein, Fe3O4NPs acted as supporters for AuNPs, which contributed to enhance the efficiency of electron transfer. On the basis of the measurement of Mott–Schottky plots of graphene and metal anchored hybrids, the catalysis mechanism was elucidated by the decrease of Fermi level resulted from the chemical doping behavior. Notably, the catalytic activity was able to be regulated by the adsorption and desorption of single-stranded DNA molecules, which laid a basis for its utilization in the construction of single-stranded DNA-based colorimetric biosensors. This strategy not only simplified the operation process including labeling, modification, and imprinting, but also protected the intrinsic affinity between the target and biological probe. Accordingly, based on the peroxidase-like activity and its controllability, our prepared nanohybrids was successfully adopted in the visualized and label-free sensing detections of glucose, sequence-specific DNA, mismatched nucleotides, and oxytetracycline.
Abstract This paper reports the use of a tetracycline (TC) sensor constructed from a combination of molecularly imprinted polymer (MIP) and gold nanoparticles modified multiwall carbon nanotubes (MWNTs‐GNPs). The results demonstrated that the amount of recognition sites in the polymer was significantly increased and the electron transfer ability of the sensor was improved. The relationship between the peak current and the TC concentration was linear in the range from 0.1 to 40 mg L −1 , and the detection limit was 0.04 mg L −1 ( S / N =3). The peak current to TC was 4.3, 6.2 and 6.8 times larger than that of oxytetracycline, chloramphenicol and nafcillin, respectively. Thus, the combination of MIP and MWNTs‐GNPs provides a sensitive and selective electrochemical detection method for tetracycline.
Overuse of antibiotics has led to multidrug resistance in bacteria, posing a tremendous challenge to the healthcare system. There is an urgent need to explore unconventional strategies to overcome this issue. Herein, for the first time, we report a capacitive Co3 O4 nanowire (NW) electrode coated on flexible carbon cloth, which is capable of eliminating bacteria while discharging, for the treatment of skin infection. Benefiting from the unique NW-like morphology, the Co3 O4 NW electrode with increased active sites and enhanced capacitive property exhibits a prominent antibacterial effect against both Gram-positive and Gram-negative bacteria after charging at a low voltage of 2 V for 30 min. Furthermore, the electrode is demonstrated to be recharged for multiple antibacterial treatment cycles without significant change of antibacterial activity, allowing for practical use in a non-clinical setting. More importantly, this Co3 O4 NW electrode is capable of damaging bacterial cell membrane and inducing the accumulation of intracellular reactive oxygen species without impairing viability of skin keratinocytes. In a mouse model of bacterial skin infection, the Co3 O4 electrode shows significant therapeutic efficacy by eradicating colonized bacteria, thus accelerating the healing process of infected wounds. This nanostructured capacitive electrode provides an antibiotic-free, rechargeable, and wearable approach to treat bacterial skin infection.
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