Potential biomarkers screening of Polygonum multiflorum radix-induced liver injury based on metabonomics analysis of clinical samples.

ETHNOPHARMACOLOGICAL RELEVANCE: Polygonum multiflorum Radix (PMR) is the dried root tuber of Polygonum multiflorum Thunb., which has been used in the clinic for a variety of pharmacological activities. However, Polygonum multiflorum Radix-induced liver injury (PMR-ILI) has been reported in recent years, which has limited its clinical use to some extent. The occurrence of PMR-ILI is not universal, so finding the different metabolic characteristics between PMR-ILI and Polygonum multiflorum Radix-tolerance group (PMR-T) is very important for the PMR rational clinical application and PMR-ILI early clinical diagnosis. METHODS: In this study, 6 clinical plasma samples of PMR-ILI and 13 PMR-T were collected and analyzed by high-resolution liquid chromatography-mass spectrometry. Firstly, the differential metabolites of the two groups were screened by conventional screening methods such as multivariate statistical analysis. Secondly, the characteristic metabolites with greater contribution, correlation with liver injury and high sensitivity were screened by correlation analysis with clinical liver injury indicators, random forest analysis, and receiver operating characteristic curve (ROC). RESULTS: After multivariate statistical analysis and screening analysis, 29 differential metabolites were identified. Compared with PMR-T group, the metabolism of glycerol and phospholipid, glutamine and glutamate, phenylalanine, sphingolipid and tryptophan in PMR-ILI group were disturbed. After correlation analysis with liver injury indexes and random forest screening, 8 potential biomarkers closely related to clinical liver injury were obtained. Finally, 3 potential biomarkers with high expression in PMR-ILI, hypoxanthine, LysoPC(P-16:0/0:0) and taurochenodesoxycholic acid, were screened out through the analysis of ROC, which can provide a basis for the early clinical diagnosis. CONCLUSION: Based on the analysis of the PMR-ILI and PMR-T plasma samples by LC-MS, three biomarkers of clinical liver injury of Polygonum multiflorum Radix were selected: hypoxanthine, LysoPC(P-16:0/0:0) and taurochenodeoxycholic acid.

Integrated spatially resolved metabolomics and network toxicology to investigate the hepatotoxicity mechanisms of component D of Polygonum multiflorum Thunb.

ETHNOPHARMACOLOGICAL RELEVANCE: The liver toxicity of Reynoutria multiflora (Thunb.) Moldenke. (Polygonaceae) (Polygonum multiflorum Thunb, PM) has always attracted much attention, but the related toxicity materials and mechanisms have not been elucidated due to multi-component and multi-target characteristics. In previous hepatotoxicity screening, different components of PM were first evaluated and the hepatotoxicity of component D [95% ethanol (EtOH) elution] in a 70% EtOH extract of PM (PM-D) showed the highest hepatotoxicity. Furthermore, the main components of PM-D were identified and their hepatotoxicity was evaluated based on a zebrafish embryo model. However, the hepatotoxicity mechanism of PM-D is unknown. AIM OF THE STUDY: This work is to explore the hepatotoxicity mechanisms of PM-D by integrating network toxicology and spatially resolved metabolomics strategy. MATERIALS AND METHODS: A hepatotoxicity interaction network of PM-D was constructed based on toxicity target prediction for eight key toxic ingredients and a hepatotoxicity target collection. Then the key signaling pathways were enriched, and molecular docking verification was implemented to evaluate the ability of toxic ingredients to bind to the core targets. The pathological changes of liver tissues and serum biochemical assays of mice were used to evaluate the liver injury effect of mice with oral administration of PM-D. Furthermore, spatially resolved metabolomics was used to visualize significant differences in metabolic profiles in mice after drug administration, to screen hepatotoxicity-related biomarkers and analyze metabolic pathways. RESULTS: The contents of four key toxic compounds in PM-D were detected. Network toxicology identified 30 potential targets of liver toxicity of PM-D. GO and KEGG enrichment analyses indicated that the hepatotoxicity of PM-D involved multiple biological activities, including cellular response to endogenous stimulus, organonitrogen compound metabolic process, regulation of the apoptotic process, regulation of kinase, regulation of reactive oxygen species metabolic process and signaling pathways including PI3K-Akt, AMPK, MAPK, mTOR, Ras and HIF-1. The molecular docking confirmed the high binding activity of 8 key toxic ingredients with 10 core targets, including mTOR, PIK3CA, AKT1, and EGFR. The high distribution of metabolites of PM-D in the liver of administrated mice was recognized by mass spectrometry imaging. Spatially resolved metabolomics results revealed significant changes in metabolic profiles after PM-D administration, and metabolites such as taurine, taurocholic acid, adenosine, and acyl-carnitines were associated with PM-D-induced liver injury. Enrichment analyses of metabolic pathways revealed tht linolenic acid and linoleic acid metabolism, carnitine synthesis, oxidation of branched-chain fatty acids, and six other metabolic pathways were significantly changed. Comprehensive analysis revealed that the hepatotoxicity caused by PM-D was closely related to cholestasis, mitochondrial damage, oxidative stress and energy metabolism, and lipid metabolism disorders. CONCLUSIONS: In this study, the hepatotoxicity mechanisms of PM-D were comprehensively identified through an integrated spatially resolved metabolomics and network toxicology strategy, providing a theoretical foundation for the toxicity mechanisms of PM and its safe clinical application.

A review of the processed Polygonum multiflorum (Thunb.) for hepatoprotection: Clinical use, pharmacology and toxicology.

ETHNOPHARMACOLOGICAL RELEVANCE: Polygonum multiflorum (Thunb.) (PMT) is a member of Polygonaceae. Traditional Chinese medicine considers that the processed PMT can tonify liver, nourish blood and blacken hair. In recent years, the processed PMT and its active ingredients have significant therapeutic effects on nonalcoholic fatty liver disease, alcoholic fatty liver disease, viral hepatitis, liver fibrosis and liver cancer. AIM OF THE STUDY: The main purpose of this review is to provide a critical appraisal of the existing knowledge on the clinical application, hepatoprotective pharmacology and hepatotoxicity, it provides a comprehensive evaluation of the liver function of the processed PMT. MATERIALS AND METHODS: A detailed literature search was conducted using various online search engines, such as Pubmed, Google Scholar, Mendeley, Web of Science and China National Knowledge Infrastructure (CNKI) database. The main active components of the processed PMT and the important factors in the occurrence and development of liver diseases are used as key words to carry out detailed literature retrieval. RESULTS: In animal and cell models, the processed PMT and active components can treat various liver diseases, such as fatty liver induced by high-fat diet, liver injury and fibrosis induced by drugs, viral transfected hepatitis, hepatocellular carcinoma, etc. They can protect liver by regulating lipid metabolism related enzymes, resisting insulin resistance, decreasing the expression of inflammatory cytokines, inhibiting the activation of hepatic stellate cells, reducing generation of extracellular matrix, promoting cancer cell apoptosis and controlling the growth of tumor cells, etc. However, improperly using of the processed PMT can cause liver injury, which is associated with the standardization of processing, the constitution of the patients, the characteristics of the disease, and the administration of dosage and time. CONCLUSION: The processed PMT can treat various liver diseases via reasonably using, and the active compounds (2,3,5,4'-tetrahydroxystilbene-2-O-ß-D-glucoside, emodin, physcion, etc.) are promising candidate drugs for developing new liver protective agents. However, some components have a "toxic-effective" bidirectional effect, which should be used cautiously.

[Influence of specification on chemical composition of dissolution and hepatocytes toxicity of Polygonum multiflorum].

According to different toxicities of various aqueous extracts of Polygonum multiflorum on hepatocyte, the impacts of chemical composition on the safety of P. multiforum was studied. In this study, 8 main chemical compositions in aqueous extracts of P. multiflorum were determined by the established HPLC method; at the same time, the inhibition ratios of different aqueous extracts of P. multiflorum on L02 cell were determined. Afterwards, the potential compounds related to the toxicity of P. multiforum were tentatively found through a multiple correlation analysis. The results showed that P. multiforum with different chemical compositions exhibited great differences in dissolution. The hepatocyte toxicity of P. multiflorum powder was much greater than P. multiflorum lumps. In addition, three constituents closely related to toxicity of P. multiflorum were found by multiple correlation analysis. The study revealed that chemical composition of P. multiflorum is closely related to the hepatotoxicity, and the hepatotoxicity of P. multiflorum powder is greater than that of other dosage forms. This study indicates that P. multiflorum with different chemical compositions show varying toxicity, which therefore shall be given high attention.

[Exploration research on hepatotoxic constituents from Polygonum multiflorum root].

By observing the cytotoxic effects of anthraquinones on HepG2 cell and using the precision-cut liver slices technique to authenticate the cytotoxic constituents, the paper aims to explore the material basis of Polygonum multiflorum root to cause liver toxicity. Firstly, MTT method was used to detect the effect of 11 anthraquinone derivatives on HepG2 cell. Then, the clear cytotoxic ingredients were co-cultured with rat liver slices for 6h respectively, and the liver tissue homogenate was prepared. BCA method was used to determine the content of protein in the homogenate and continuous monitoring method was used to monitor the leakage of alanine aminotransferase (ALT), aspartate aminotransferase (AST), gamma-glutamine amino transpeptidase (GGT) and lactate dehydrogenase (LDH). The toxic effect of these ingredients on liver tissue was tested by calculating the leakage rate of the monitored enzymes. As a result, rhein, emodin, physcion-8-O-ß-D-glucopyranoside and physcion-8-O-(6'-O-acetyl)-ß-D-glucopyranoside showed cytotoxic effects on HepG2 cell and their IC50 values were 71.07, 125.62, 242.27, 402.32 µmol•L⁻¹ respectively, but the other 7 compounds are less toxic and their IC50 values can not be calculated. The precision-cut liver slices tests showed that rhein group of 400 µmol•L⁻¹ concentration significantly increased the leakage rate of ALT, AST and LDH (P<0.01), and the rhein group of 100 µmol•L⁻¹ concentration only increased the leakage rate of LDH (P<0.05). With the increase of rhein concentration, the protein content in liver slices decreased significantly (P<0.05) with a certain range of does. Emodin group of 400 µmol•L⁻¹ concentration significantly increased the leakage rate of ALT, GGT and LDH (P<0.01). Physcion-8-O-ß-D-glucopyranoside group of 800 µmol•L⁻¹ concentration also significantly increased the leakage rate of ALT, AST and LDH (P<0.01 or P<0.05), but the group of 200 µmol•L⁻¹ concentration only significantly increased the LDH leakage (P<0.05). Along with the increase of the concentration of physcion-8-O-ß-D-glucopyranoside, the leakage rate of ALT, AST and LDH showed a trend of increase, but the protein content in liver slices was in decline. Furthermore, MTT reduction ability of liver slices significantly decreased (P<0.01) in the physcion-8-O-ß-D-glucopyranoside group of 800 µmol•L⁻¹ concentration. The results suggested that rhein, emodin and physcion-8-O-ß-D-glucopyranoside at high concentrations (≥400 µmol•L⁻¹) can produce some damage to the liver tissue. However, the exposure levels of these constituents are very low, so to reach the toxic concentration (400 µmol•L⁻¹ or 800 µmol•L⁻¹) an adult of 65 kg body weight will need at least a single oral 4 898 g, 339 g and 5 581 g of P.multiflorum root respectively, which is far from the statutory dose of crude P. multiflorum root (3-6 g) or its processed product (6-12 g). Therefore, the conclusion that anthraquinones are the prime constituents of the hepatotoxicity of P. multiflorum root are still not be proved.