Formulation of DNA Nanocomposites: Towards Functional Materials for Protein Expression

A Critical View on the Use of DNA Hydrogels in Cell-Free Protein Synthesis

Numerous studies have reported in the past that the use of protein-encoding DNA hydrogels as templates for cell-free protein synthesis (CFPS) leads to better yields than the use of conventional templates such as plasmids or PCR fragments. Systematic investigation of different types of bulk materials from pure DNA hydrogels and DNA hydrogel composites using a commercially available CFPS kit showed no evidence of improved expression efficiency. However, protein-coding DNA hydrogels were advantageously used in microfluidic reactors as immobilized templates for repetitive protein production, suggesting that DNA-based materials offer potential for future developments in high-throughput profiling or rapid in situ characterization of proteins.

Macrophage-Targeting DNA Nanomaterials: A Future Direction of Biological Therapy

DNA can be used for precise construction of complex and flexible micro-nanostructures, including DNA origami, frame nucleic acids, and DNA hydrogels. DNA nanomaterials have good biocompatibility and can enter macrophages via scavenger receptor-mediated endocytosis. DNA nanomaterials can be uniquely and flexibly designed to ensure efficient uptake by macrophages, which represents a novel strategy to regulate macrophage function. With the development of nanotechnology, major advances have been made in the design and manufacturing of DNA nanomaterials for clinical therapy. In diseases accompanied by macrophage disturbances including tumor, infectious diseases, arthritis, fibrosis, acute lung injury, and atherosclerosis, DNA nanomaterials received considerable attention as potential treatments. However, we lack sufficient information to guarantee precise targeting of macrophages by DNA nanomaterials, which precludes their therapeutic applications. In this review, we summarize recent studies of macrophage-targeting DNA nanomaterials and discuss the limitations and challenges of this approach with regard to its potential use as a biological therapy.

Exploring the diverse biomedical applications of programmable and multifunctional DNA nanomaterials

DNA nanoparticles hold great promise for a range of biological applications, including the development of cutting-edge treatments and diagnostic tests. Their subnanometer-level addressability enables precise, specific modifications with a variety of chemical and biological entities, making them ideal as diagnostic instruments and carriers for targeted delivery. This paper focuses on the potential of DNA nanomaterials, which offer scalability, programmability, and functionality. For example, they can be engineered to provide highly specific biosensing and bioimaging capabilities and show promise as a platform for disease diagnosis and treatment. Successful operation of various biomedical nanomaterials has been demonstrated both in vitro and in vivo. However, there are still significant challenges to overcome, including the need to improve the scalability and reliability of the technology, and to ensure safety in clinical applications. We discuss these challenges and opportunities in detail and highlight the progress and prospects of DNA nanotechnology for biomedical applications.

Chromatin extracted from common carp testis as an economical and easily available adsorbent for ethidium bromide decontamination

The waste of ethidium bromide (EtBr) used in the laboratory will bring a great burden to the environment, which need to be solved urgently. In the present paper, an efficient and inexpensive method for EtBr removal using chromatin extracted from common carp testis was investigated. The observation of fluorescence microscopy showed that chromatin had similar property to DNA for selective adsorption of EtBr. The results of batch adsorption showed that the removal efficiency of EtBr by chromatin exceeded 99% at pH 7.4 and 30 °C for 3 min with the EtBr concentration of 2 mg L⁻¹ and the chromatin dosage of 0.5 g L⁻¹, and the maximum adsorption amount of chromatin was 45.73 mg g⁻¹. Further, the analysis of kinetic and isotherm suggested that the adsorption followed Pseudo-second-order kinetics and Langmuir isotherm model, and the calculated maximum theoretical adsorption amount of chromatin to EtBr was 48.08 mg g⁻¹. According to thermodynamic analysis, chromatin adsorption of EtBr was a spontaneous process dominated by hydrogen bonding and van der Waals forces. This work will not only offer an adsorbent for EtBr decontamination, also provide a possibility for EtBr analogs removal.

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The inexpensive bio-adsorbent was prepared from common carp testis by-production.

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The bio-adsorbent was applied in EtBr decontamination.

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The maximum adsorption amount of EtBr by chromatin was up to 45.73 mg g⁻¹, while the maximum adsorption amount of EtBr by activated carbon was only 0.46 mg g⁻¹.

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The adsorption of EtBr by chromatin followed Pseudo-second-order kinetics and Langmuir isotherm model.