Polyethylene microplastics induced inflammation via the miR-21/IRAK4/NF-κB axis resulting to endoplasmic reticulum stress and apoptosis in muscle of carp.

As a widespread environmental pollutant, microplastics pose a great threat to the tissues and organs of aquatic animals. The carp's muscles are necessary for movement and survival. However, the mechanism of injury of polyethylene microplastics (PE-MPs) to carp muscle remains unclear. Therefore, in this study, PE-MPs with the diameter of 8 µm and the concentration of 1000 ng/L were used to feed carp for 21 days, and polyethylene microplastic treatment groups was established. The results showed that PE-MPs could cause structural abnormalities and disarrangement of muscle fibers, and aggravate oxidative stress in muscles. Exposure to PE-MPs reduced microRNA (miR-21) in muscle tissue, negatively regulated Interleukin-1 Receptor Associated Kinase 4 (IRAK4), activated Nuclear Factor Kappa-B (NF-κB) pathway, induced inflammation, and led to endoplasmic reticulum stress and apoptosis. The present study provides different targets for the prevention of muscle injury induced by polyethylene microplastics.

A cyanine dye probe for K+ detection based on DNA construction of G-quadruplex.

Potassium ion (K+) plays an important role in the maintenance of cellular biological process for human health. Thus, the detection of K+ is very important. Here, based on the interaction between thiamonomethinecyanine dye and G-quadruplex formation sequence (PW17), K+ detection spectrum was characterized by UV-Vis spectrometry. The single-stranded sequence of PW17 can fold into G-quadruplex in the presence of K+. PW17 can induce a dimer-to-monomer transition of the absorption spectrum of cyanine dyes. This method shows high specificity against some other alkali cations, even at high concentrations of Na+. Further, this detection strategy can realize the detection of K+ in tap water.

Study on the interaction of a cyanine dye with human serum transferrin.

Complexation between the primary carrier of ligands in blood plasma, human serum transferrin (Tf), and a cyanine dye, 3,3'-di(3-sulfopropyl)-4,5,4',5'-dibenzo-9-phenyl-thiacarbocyanine-triethylam monium salt (PTC) was investigated using fluorescence spectra, UV/Vis absorption spectra, synchronous fluorescence spectra, circular dichroism (CD) and molecular dynamic docking. The experimental results demonstrate that the formation of PTC-Tf complex is stabilized by van der Waal's interactions and hydrogen bonds, and the binding constants were found to be 8.55 × 10(6), 8.19 × 10(6) and 1.75 × 10(4) M(-1). Moreover, fluorescence experiments prove that the operational mechanism for the fluorescence quenching is static quenching and non-radiative energy transfer. Structural investigation of the PTC-Tf complexes via synchronous fluorescence spectra and CD showed that the structure of Tf became more stable with a major increase in the α-helix content and increased polarity around the tryptophan residues after PTC binding. In addition, molecular modeling highlights the residues located in the N-lobe, which retain high affinity for PTC. The mode of action of the PTC-Tf complex is illustrated by these results, and may provide an effective pathway for the transport and targeted delivery of antitumor agents.

Studies on the binding of fulvic acid with transferrin by spectroscopic analysis.

Transferrin has shown potential in the delivery of anticancer drugs into primarily proliferating cancer cells that over-express transferrin receptors. Fulvic acid has a wide range of biological and pharmacological activities which caused widespread concerns, the interaction of fulvic acid with human serum transferrin (Tf) has great significance for gaining a deeper insight about anticancer activities of fulvic acid. In this study, the mechanism of interaction between fulvic acid and Tf, has been investigated by using fluorescence quenching, thermodynamics, synchronous fluorescence and circular dichroism (CD) under physiological condition. Our results have shown that fulvic acid binds to Tf and form a new complex, and the calculated apparent association constants are 5.04×10(8) M(-1), 5.48×10(7) M(-1), 7.38×10(6) M(-1) from the fluorescence quenching at 288 K, 298 K, and 310 K. The thermodynamic parameters indicate that hydrogen bonding and weak van der Waals are involved in the interaction between fulvic acid and Tf. The binding of fulvic acid to Tf causes the α-helix structure content of the protein to reduce, and resulting that peptide chains of Tf become more stretched. Our results have indicated a mechanism of the interaction between fulvic acid and Tf, which may provide information for possible design of methods to deliver drug molecules via transferrin to target tissues and cells effectively.

[Investigation on the cyanine dyes supramolecular assembly and chiral inducement by fulvic acid].

Using cyanine dyes supramolecular as molecular probes to mark FA has important significance in life sciences and pharmaceutical chemistry, which can detect FA as drug efficacy mechanism and the change in physiological activity. In the present paper, we investigated supramolecular assembly and chiral inducement of cyanine dyes template by FA with absorption and circular dichroism (CD) spectra. The result suggests that FA can induce cyanine dyes from J-aggregation to monomer along with different colors change and has strong affinity with cyanine dye monomer. The template of FA not only can translate the chirality of MTC H-aggregation to other two states, but also induce ETC J-aggregation to molecular rearrangement and form left-handed helix of J-aggregates. Besides, the association of PTC with FA, i. e. binding to FA gave rise to the J-aggregation CD signals. Meanwhile, it was inferred that the meso substituent of cyanine dyes play an important role in the interaction between FA and the J-aggregation: the smaller the meso substituent, the higher the affinity interacted with FA. Clearly, the binding abilities between cyanine dyes and FA follow the order of MTC>ETC>PTC. These results support that the cyanine dyes supramolecular aggregates can be used as a kind of excellent molecular probes for specific recognition of FA and achieve the effect of visual inspection.

The effect of the skeleton structure of flavanone and flavonoid on interaction with transferrin.

Transferrin has been exploited as a potential drug carrier for targeted drug delivery into cancer cells, which express high levels of transferrin receptors. In the present study, we identified specific structural features in flavonoids that were critical for binding to transferrin. Flavanone naringenin and flavonoid apigenin, two flavonoids with characteristic flavonoid core structures were selected for the study of the effects of C2-C3 single bond in the C-ring on transferrin binding. We determined the binding affinities by fluorescence quenching experiments and investigated the binding modes by CD spectra and molecular modeling. Our results demonstrated that naringenin bound transferrin with an affinity almost 100 times higher than that of apigenin attributed to its higher structural flexibility and lower acidity compared with apigenin. Our docking study showed that naringenin had stronger van der Waals interactions with transferrin, which was believed to contribute to its higher binding affinity. We also found that naringenin-binding induced greater increase in the α-helix content in transferrin than apigenin, suggesting that transferrin became more compact upon association with naringenin. Our study demonstrated that naringenin was a ligand for transferrin with good affinity. The results reported herein can facilitate the design and development of drugs that bind transferrin with high affinity.