Physiological and transcriptomic study reveal SeNPs-mediated AsIII stress detoxification mechanisms involved modulation of antioxidants, metal transporters, and transcription factors in Glycine max L. (Merr.) roots.

Physiological changes and genome-wide alteration in gene expression were performed in soybean (Glycine max [L.] Merr.) roots exposed to AsⅢ (25 µmol/L) alone and supplemented with selenium nanoparticles (SeNPs) at the concentration of 10 and 25 µmol/L at the V2 growth stage. Excessive arsenic in the root zone poses a potential threat to soybean yield, particularly to roots, due to the limited translocation of AsIII from root to shoot in the case of soybean. We hypothesized that SeNPs can relieve AsⅢ toxicity to soybean root by reducing the AsⅢ uptake and regulating the internal tolerance mechanism of the plants. Results accomplished that SeNPs had positive impact on soybean dry weight and roots parameters under AsⅢ stress. Then, we further evaluated physiological indexes, whole genome transcriptomic analysis and quantitative real-time PCR to elucidate the underlying mechanism of AsⅢ tolerance under SeNPs supplementation. Under the condition of AsⅢ-stress, SeNPs exposure significantly reduced the electrolyte leakage, O2-•, H2O2 and MDA accumulation while increasing the antioxidants level. The RNA-seq dataset revealed total of 5819 up and 7231 down expressed DEGs across all libraries. The number of exclusively regulated genes were higher under As + SeNP10 (4909) treatment than in the AsⅢ-alone (4830) and As + SeNP25 (3311) treatments. The KEGG and GO analyses revealed that stress responsive DEGs such as glutathione S-transferase, glutathione peroxidase, ascorbate, glutaredoxin, thioredoxin, and phytochelatins synthase are responsible for AsⅢ tolerance under the SeNPs supplementation. Similarly, sulfate transporter, and ABC transporters (ATP-binding cassettes) expression were induced, and aquaporin channels related DEGs expression were reduced under SeNPs application in AsⅢ exposure condition. Furthermore, the expression of molecular chaperones (HSP) and transcription factors (MYB, bZIP, bHLH, and HSFs) were increased in SeNPs treatment groups. These results provide vital information of AsⅢ tolerance mechanism in response to SeNPs in soybean. We suggest that functional characterization of these genes will help us learn more about the SeNPs responsive arsenic tolerance mechanism in soybean.

[Research progress on antitumor effect and molecular mechanism of capsaicin].

Capsaicin is a lipid-soluble vanillin alkaloid extracted from Capsicum plants in the Solanaceae family, which is the main active ingredient in capsicum, with multiple functions such as anti-inflammation, analgesia, cardiovascular expansion, and gastric mucosa protection. Recently, capsaicin has been confirmed as a potential antitumor compound. It can induce cell cycle arrest, inhibit cancer cell proliferation, metastasis, invasion, and angiogenesis, and promote apoptosis or autophagy in malignancy cell models and animal models of lung cancer, breast cancer, gastric cancer, and liver cancer. Meanwhile, capsaicin shows a synergistic antitumor effect when combined with other antitumor drugs such as sorafenib. Based on the recent literature on the antitumor effect of capsaicin, the present study analyzed the molecular mechanism of capsaicin in resisting tumors by inducing apoptosis and reviewed the effects of capsaicin in inducing tumor cell cycle arrest, inhibiting tumor cell proliferation, metastasis, and angiogenesis, and combating tumors with other drugs, thereby providing a theoretical basis for further research of capsaicin and its rational development and utilization.

[Toxicity mechanism of Rhododendri Mollis Flos: based on serum metabolomics and network toxicology].

This study aims to explore the toxicity mechanism of Rhododendri Mollis Flos(RMF) based on serum metabolomics and network toxicology. The toxic effect of RMF on normal rats was evaluated according to the symptoms, serum biochemical indexes, and histopathology. Serum metabolomics was combined with multivariate statistical analysis to search endogenous differential metabolites and related metabolic pathways. The toxic components, targets, and signaling pathways of RMF were screened by network toxicology technique, and the component-target-metabolite-metabolic pathway network was established with the help of serum metabolomics. The result suggested the neurotoxicity, hepatotoxicity, and cardiotoxicity of RMF. A total of 31 differential metabolites and 10 main metabolic pathways were identified by serum metabolomics, and 11 toxic components, 332 related target genes and 141 main signaling pathways were screened out by network toxicology. Further analysis yielded 7 key toxic components: grayanotoxin Ⅲ,grayanotoxinⅠ, rhodojaponin Ⅱ, rhodojaponin Ⅴ, rhodojaponin Ⅵ, rhodojaponin Ⅶ, and kalmanol, which acted on the following 12 key targets: androgen receptor(AR), albumin(ALB), estrogen receptor ß(ESR2), sex-hormone binding globulin(SHBG), type 11 hydroxysteroid(17-beta) dehydrogenase(HSD17 B11), estrogen receptor α(ESR1), retinoic X receptor-gamma(RXRG), lactate dehydrogenase type C(LDHC), Aldo-keto reductase(AKR) 1 C family member 3(AKR1 C3), ATP binding cassette subfamily B member 1(ABCB1), UDP-glucuronosyltransferase 2 B7(UGT2 B7), and glutamate-ammonia ligase(GLUL). These targets interfered with the metabolism of gamma-aminobutyric acid, estriol, testosterone, retinoic acid, 2-oxobutyric acid, and affected 4 key metabolic pathways of alanine, aspartate and glutamate metabolism, cysteine and methionine metabolism, steroid hormone biosynthesis, and retinol metabolism. RMF exerts toxic effect on multiple systems through multiple components, targets, and pathways. Through the analysis of key toxic components, target genes, metabolites, and metabolic pathways, this study unveiled the mechanism of potential neurotoxicity, cardiotoxicity, and hepatotoxicity of RMF, which is expected to provide a clue for the basic research on toxic Chinese medicinals.

Berberine exerts its antineoplastic effects by reversing the Warburg effect via downregulation of the Akt/mTOR/GLUT1 signaling pathway.

Glucose transporter 1 (GLUT1) plays a primary role in the glucose metabolism of cancer cells. However, to the best of our knowledge, there are currently no anticancer drugs that inhibit GLUT1 function. The present study aimed to investigate the antineoplastic activity of berberine (BBR), the main active ingredient in numerous Traditional Chinese medicinal herbs, on HepG2 and MCF7 cells. The results of Cell Counting Kit­8 assay, colony formation assay and flow cytometry revealed that BBR effectively inhibited the proliferation of tumor cells, and induced G2/M cell cycle arrest and apoptosis. Notably, the results of luminescence ATP detection assay and glucose uptake assay showed that BBR also significantly inhibited ATP synthesis and markedly decreased the glucose uptake ability, which suggested that the antitumor effect of BBR may occur via reversal of the Warburg effect. In addition, the results of reverse transcription­quantitative PCR, western blotting and immunofluorescence staining indicated that BBR downregulated the protein expression levels of GLUT1, maintained the cytoplasmic internalization of GLUT1 and suppressed the Akt/mTOR signaling pathway in both HepG2 and MCF7 cell lines. Augmentation of Akt phosphorylation levels by the Akt activator, SC79, abolished the BBR­induced decrease in ATP synthesis, glucose uptake, GLUT1 expression and cell proliferation, and reversed the proapoptotic effect of BBR. These findings indicated that the antineoplastic effect of BBR may involve the reversal of the Warburg effect by downregulating the Akt/mTOR/GLUT1 signaling pathway. Furthermore, the results of the co­immunoprecipitation assay demonstrated that BBR increased the interaction between ubiquitin conjugating enzyme E2 I (Ubc9) and GLUT1, which suggested that Ubc9 may mediate the proteasomal degradation of GLUT1. On the other hand, BBR decreased the interaction between Gα­interacting protein­interacting protein at the C­terminus (GIPC) and GLUT1, which suggested that the retention of GLUT1 in the cytoplasm may be achieved by inhibiting the interaction between GLUT1 and GIPC, thereby suppressing the glucose transporter function of GLUT1. The results of the present study provided a theoretical basis for the application of the Traditional Chinese medicine component, BBR, for cancer treatment.

[Studies on in vitro culture of adventitious root in Salvia miltiorrhiza].

OBJECTIVE: To study the culture of adventitious root of Salvia miltiorrhiza in vitro systemically. METHOD: Effects of sucrose concentrations, medium pH, inoculum size and plant growth regulators on adventitious root growth and secondary metabolites production in S. miltiorrhiza were investigated. RESULT: With the increase of initial sucrose concentration, adventitious root growth rates increased and tanshinone II A content decreased, while content of protocatechuic aldehyde showed a broken line change and its highest production was obtained under 30 g x L(-1) sucrose in the medium. As for the effect of medium pH, medium pH of 6.5, 5.5 (or 6.0) and 5.8 was favorable for adventitious root growth, tanshinone II A and protocatechuic aldehyde synthesis respectively. Furthermore, adventitious root growth, rate was greatly increased when inoculum size was 2.5%. MS medium added with 0.5 mg x L(-1) KT was much favorable for tanshinone II A and protocatechuic aldehyde accumulation. CONCLUSION: Parameters including sucrose concentrations, medium pH, inoculum size and plant growth regulators have distinct effects on the in vitro culture of adventitious root growth and secondary metabolites synthesis of S. miltiorrhiza.

[Effects of mineral cations on the accumulation of tanshinone II A and protocatechuic aldehyde in the adventitious root culture of Salvia niltiorrhiza].

OBJECTIVE: To study the effects of mineral cations on the growth of Salvia niltiorrhiza adventitious roots and the accumulation of tanshinone II A and protocatechuic aldehyde. METHOD: The adventitious roots were cultured under different concentrations of metal cations and the contents of tanshinone II A and protocatechuic aldehyde were determined by HPLC. RESULT: Fe2 + and Mn2+ in MS medium are suitable for adventitious root growth, but Cu2+ and Mg2+ in high concentration could improve root proliferation, and Zn2+ has no obvious effect on root growth. As for tanshinone II A and protocatechuic aldehyde biosynthesis, Cu2+ and Zn2+ would inhibit the biosynthesis of protocatechuic aldehyde, furthermore, proper Fe2+ and Mg2+ concentration could advance the biosynthesis of protocatechuic aldehyde, whereas, Mn2+ in high concentration could accelerate the biosynthesis of protocatechuic aldehyde. Cu2+, Zn2+, Mg2+ in low concentration and Fe2+ and Mn2+ in high concentration would all advance the biosynthesis of tanshinone II A. CONCLUSION: The mineral cations have obvious effects on the secondary metabolites biosynthesis in adventitious root culture of S. niltiorrhiza.