Preface to the special issue: biotechnology of plastic waste degradation and valorization / 生物工程学报

Synthetic plastics have been widely used in various fields of the national economy and are the pillar industry. However, irregular production, plastic product use, and plastic waste piling have caused long-term accumulation in the environment, contributing considerably to the global solid waste stream and environmental plastic pollution, which has become a global problem to be solved. Biodegradation has recently emerged as a viable disposal method for a circular plastic economy and has become a thriving research area. In recent years, important breakthroughs have been made in the screening, isolation, and identification of plastic-degrading microorganisms/enzyme resources and their further engineering, which provide new ideas and solutions for treating microplastics in the environment and the closed-loop bio-recycling of waste plastics. On the other hand, the use of microorganisms (pure cultures or consortia) to further transform different plastic degradants into biodegradable plastics and other compounds with high added value is of great significance, promoting the development of a plastic recycling economy and reducing the carbon emission of plastics in their life cycle. We edited a Special Issue on the topic of "Biotechnology of Plastic Waste Degradation and Valorization", focusing on the researches progress in three aspects: Mining microbial and enzyme resources for plastic biodegradation, Design and engineering of plastic depolymerase, and biological high-value transformation of plastic degradants. In total, 16 papers have been collected in this issue including reviews, comments, and research articles, which provide reference and guidance for further development of plastic waste degradation and valorization biotechnology.

Time-course monitoring of in vitro biotransformation reaction via solid-phase microextraction-ambient mass spectrometry approaches / 药物分析学报

The solid-phase microextraction technique quantifies analytes without considerably affecting the sample composition.Herein,a proof-of-concept study was conducted to demonstrate the use of coated probe electrospray ionization(coated-PESI)and coated blade spray(CBS)as ambient mass spectrometry ap-proaches for monitoring drug biotransformation.The ability of these methods was investigated for monitoring the dephosphorylation of a prodrug,combretastatin A4 phosphate(CA4P),into its active form,combretastatin A4(CA4),in a cell culture medium supplemented with fetal bovine serum.The CBS spot analysis was modified to achieve the same extraction efficiency as protein precipitation and ob-tained results in 7 min.Because coated-PESI performs extraction without consuming any samples,it is the preferred technique in the case of a limited sample volume.Although coated-PESI only extracts small quantities of analytes,it uses the desorption solvent volume of 5-10 pL,resulting in high sensitivity,thus allowing the detection of compounds after only 1 min of extraction.The biotransformation of CA4P into CA4 via phosphatases occurs within the simple matrix,and the proposed sample preparation techniques are suitable for monitoring the biotransformation.

Research progress on the biotransformation of flavonoid glycosides in Epimedii Folium / 中国药房

Flavonoid glycosides are the main active constituents of Epimedii Folium and its related plants. They can be divided into polyglycosides and low glycosides according to the number of glycosyl group. The polyglycosides of Epimedii Folium can be transformed into low glycosides after biotransformation ；pharmacological activities of low glycosides in anti-tumor ，tonifying kidney yang and anti-osteoporosis are stronger than those of polyglycosides. In this paper ， the research progress about biotransformation technology of flavonoid glycosides of Epimedii Folium was reviewed. It was found that the main biotransformation pathway of flavonoid glycosides of Epimedii Folium was to obtain low glycosides by removing glycosyl group ； related methods were mainly enzymatic hydrolysis and microbial transformation ，and also included plant cell transformation ，acid hydrolysis method and synthesis method.

Herba Epimedii's biotransformation in vitro simulated gastrointestinal digestion and faecal fermentation systems / 中国药理学与毒理学杂志

OBJECTIVE Epimedium is rich in a variety of beneficial active ingredients, and has been widely used in the ethnopharmacological practices, however, its biotransformation in gastrointestinal digestions remain unclear. This study aimed to investigate the dynamic changes of components and biological activity of Epimedium in the in vitro simu? lated digestion and subsequent human faecal fermentation. METHODS The models of in vitro simulated saliva, gastric and intestinal digestion, as well as colonic fermentation were constructed to simulate the digestion process of Epimedium. The dynamic changes of components of Epimedium during the simulated digestions in vitro and subsequent human faecal fermentation were investigated by UPLC-MS, HPLC-DAD combined with principal component analysis (PCA) and multi-ingredient quantitative analysis. RESULTS A variety of metabolites with high contents were produced after 0.5 h of intestinal digestion and colonic fermentation 0.5 h. Application of PCA to HPLC data showed the obvious separation of colonic fermentation 0.5 h stage samples from other colonic fermentation stages samples (24, 48 and 72 h). Addition? ally, non-digestion and saliva digestion stage samples clustered together, and there was obvious separation between intestinal digestion samples and gastric digestion samples. The contents of epimedium C, icariin and baohuside I all increased significantly after intestinal digestion [58.70 ± 7.08, 47.15 ± 5.68 and (12.78 ± 0.55) mg · g-1] compared with gastric digestion [29.00 ± 5.65, 17.40 ± 4.55 and (2.77 ± 0.19) mg·g-1]. There were significant differences between sample after 0.5 h of colonic fermentation [64.22 ± 9.32, 51.26 ± 6.33 and (16.68 ± 3.19) mg·g-1] and other time points (24, 48 and 72 h) in components and the contents of active ingredient, and the content of these components all decreased with the fermentation time. The ability of scavenging ABTS free radicals [IC50=(0.29 ± 0.02) g · L-1] increased significantly compared with gastric digestion [(1.57 ± 0.02) g·L-1], and after 0.5 h of colonic fermentation, the ability also increased significantly. CONCLUSION Gastrointestinal digestion had a significant impact on the contents of active components in Epimedium, and the metabolism of these components mainly occurred in the colon. The intestinal digestion and colonic fermentation significantly improved the anti-ABTS activity of epimedium.

Transformation of berberine to its demethylated metabolites by the CYP51 enzyme in the gut microbiota / 药物分析学报

Berberine(BBR)is an isoquinoline alkaloid extracted from Coptis chinensis that improves diabetes,hyperlipidemia and inflammation.Due to the low oral bioavailability of BBR,its mechanism of action is closely related to the gut microbiota.This study focused on the CYP51 enzyme of intestinal bacteria to elucidate a new mechanism of BBR transformation by demethylation in the gut microbiota through multiple analytical techniques.First,the docking of BBR and CYP51 was performed;then,the pharma-cokinetics of BBR was determined in ICR mice in vivo,and the metabolism of BBR in the liver,kidney,gut microbiota and single bacterial strains was examined in vitro.Moreover,16S rRNA analysis of ICR mouse feces indicated the relationship between BBR and the gut microbiota.Finally,recombinant E.coli con-taining cyp51 gene was constructed and the CYP51 enzyme lysate was induced to express.The metabolic characteristics of BBR were analyzed in the CYP51 enzyme lysate system.The results showed that CYP51 in the gut microbiota could bind stably with BBR,and the addition of voriconazole(a specific inhibitor of CYP51)slowed down the metabolism of BBR,which prevented the production of the demethylated metabolites thalifendine and berberrubine.This study demonstrated that CYP51 promoted the deme-thylation of BBR and enhanced its intestinal absorption,providing a new method for studying the metabolic transformation mechanism of isoquinoline alkaloids in vivo.

Biotransformation of α-asarone by Alternaria longipes CGMCC 3.2875 / 中国天然药物

Biotransformation of α-asarone by Alternaria longipes CGMCC 3.2875 yielded two pairs of new neolignans, (+) (7S, 8S, 7'S, 8'R) iso-magnosalicin (1a)/(-) (7R, 8R, 7'R, 8'S) iso-magnosalicin (1b) and (+) (7R, 8R, 7'S, 8'R) magnosalicin (2a)/(-) (7S, 8S, 7'R, 8'S) magnosalicin (2b), and four known metabolites, (±) acoraminol A (3), (±) acoraminol B (4), asaraldehyde (5), and 2, 4, 5-trimethoxybenzoic acid (6). Their structures, including absolute configurations, were determined by extensive analysis of NMR spectra, X-ray crystallography, and quantum chemical ECD calculations. The cytotoxic activity and Aβ

Research progress in biosynthesis of podophyllotoxin and its derivatives / 生物工程学报

Podophyllotoxin (PTOX) is an aryl-tetralin lignan of plant origin found in some species of Podophyllum such as Dysosma versipellis, Diphylleia sinensis, and Sinopodophyllum hexandrum. Etoposide and teniposide are produced semisynthetically from PTOX and used clinically to treat several forms of cancer. As a typical representative of new drug discovery from natural products, the production of PTOX solely depends on extraction from plants, resulting in severe contradiction between supply and demand. With the advantages of unconstrained resources and eco-friendly reaction conditions, biosynthesis method has become a trend in the production of PTOX and its derivatives. In this review, we summarize the research progress of PTOX biosynthesis in plants and expound the functions of the key enzymes as well as their subcellular location. The synthetic biology for production of PTOX intermediates in a tobacco chassis is also introduced. Finally, the heterologous expression and biotransformation of PTOX in microorganisms is summarized, which sets the foundation for the efficient microbial production of PTOX using cell factories.

Boosting 5-ALA-based photodynamic therapy by a liposomal nanomedicine through intracellular iron ion regulation

5-Aminolevulinic acid (5-ALA) has been approved for clinical photodynamic therapy (PDT) due to its negligible photosensitive toxicity. However, the curative effect of 5-ALA is restricted by intracellular biotransformation inactivation of 5-ALA and potential DNA repair of tumor cells. Inspired by the crucial function of iron ions in 5-ALA transformation and DNA repair, a liposomal nanomedicine (MFLs@5-ALA/DFO) with intracellular iron ion regulation property was developed for boosting the PDT of 5-ALA, which was prepared by co-encapsulating 5-ALA and DFO (deferoxamine, a special iron chelator) into the membrane fusion liposomes (MFLs). MFLs@5-ALA/DFO showed an improved pharmaceutical behavior and rapidly fused with tumor cell membrane for 5-ALA and DFO co-delivery. MFLs@5-ALA/DFO could efficiently reduce iron ion, thus blocking the biotransformation of photosensitive protoporphyrin IX (PpIX) to heme, realizing significant accumulation of photosensitivity. Meanwhile, the activity of DNA repair enzyme was also inhibited with the reduction of iron ion, resulting in the aggravated DNA damage in tumor cells. Our findings showed MFLs@5-ALA/DFO had potential to be applied for enhanced PDT of 5-ALA.

Advances in metabolic engineering of methylotrophic yeasts / 生物工程学报

Methylotrophic yeasts are considered as promising cell factories for bio-manufacturing due to their several advantages such as tolerance to low pH and high temperature. In particular, their methanol utilization ability may help to establish a methanol biotransformation process, which will expand the substrate resource for bio-refinery and the product portfolio from methanol. This review summarize current progress on engineering methylotrophic yeasts for production of proteins and chemicals, and compare the strengths and weaknesses with the model yeast Saccharomyces cerevisiae. The challenges and possible solutions in metabolic engineering of methylotrophic yeasts are also discussed. With the developing efficient genetic tools and systems biology, the methylotrophic yeasts should play more important roles in future green bio-manufacturing.

Valor pronóstico de los marcadores bioquímicos en pacientes con COVID-19 / Prognostic value of biochemical markers in patients with COVID-19

Resumen El SARS-CoV-2 es un virus de la familia Coronaviridae, subfamilia coronavirus (CoV) y género β. Este se ha convertido en una amenaza inminente para toda la humanidad por ser el agente causal de la pandemia COVID-19, la cual llevó, por un lado, a la declaratoria de emergencia sanitaria a nivel mundial por parte de la Organización Mundial de la Salud (OMS) y, por otro, a instituir estrictas medidas de control para prevenir su contagio por parte de muchos gobiernos. En cuanto a la fisiopatología presentada en esta entidad, aunque las lesiones pulmonares han sido consideradas como las principales consecuencias de esta infección, a medida que avanza el conocimiento sobre el virus se han identificado también lesiones a nivel cardiaco, hepático y renal, que potencian la severidad de la infección y generan un mayor deterioro de los pacientes, su ingreso a las Unidades de Cuidados Intensivos y un mayor riesgo de mortalidad. Con base en esto, diversas investigaciones se han encaminado a determinar aquellos hallazgos clínicos y paraclínicos que puedan ser relevantes frente al pronóstico de los pacientes. Por lo anterior, la presente revisión aborda literatura disponible sobre los principales biomarcadores bioquímicos reportados por su asociación a daños cardiaco, hepático y renal, los cuales presentan mayor significancia para evaluar el curso, severidad, manejo y pronóstico de la infección, y cuya alteración conlleva finalmente a un mayor riesgo de mortalidad en pacientes hospitalizados que presentan COVID-19.

Abstract SARS-CoV-2 is a virus from the coronaviridae family, coronavirus (CoV) subfamily and genus β, it has become an imminent threat to all humanity as it is the causal agent of the COVID-19 pandemic, which led to On the one hand, the World Health Organization (WHO) declares a worldwide health emergency, and on the other, to institute strict control measures to prevent its spread by many governments. Regarding the pathophysiology presented in this entity, although lung lesions have been considered the main consequences of this infection, as knowledge about the virus progresses, cardiac, hepatic, and renal lesions have also been identified that enhance severity of the infection generating greater deterioration of the patients, their admission to the Intensive Care Units and a higher risk of mortality; Based on this, various investigations have aimed to determine those clinical and paraclinical findings that may be relevant to the prognosis of the patients. Therefore, this review addresses available literature on the main biochemical biomarkers reported for their association with cardiac, liver and kidney damage, which are more significant in evaluating the course, severity, management and prognosis of the infection and whose alteration ultimately leads to an increased risk of mortality in hospitalized patients presenting with COVID-19.

Farmacogenômica e Doença Cardiovascular: Onde Estamos e Para Onde Vamos / Pharmacogenomics and Cardiovascular Disease: Where are We and Where do We go from Here?

Resumo A farmacogenômica (FGx) investiga a interação entre genes e medicamentos. Através da análise de regiões específicas do DNA, informações sobre o perfil de metabolização do paciente para um determinado fármaco podem ser descritas, assim como o perfil esperado de resposta ao tratamento. Objetivamente, esse tipo de teste pode ter impacto no tratamento de pacientes que não estão respondendo adequadamente a um determinado medicamento, seja pela ausência dos efeitos esperados ou em virtude do aparecimento de efeitos adversos. Neste cenário, o objetivo desta revisão é o de informar o cardiologista clínico sobre esta importante área do conhecimento e atualizá-lo sobre o tema, procurando preencher as lacunas no que diz respeito à relação custo-benefício da aplicação da FGx nas doenças cardiovasculares, além de fornecer informações para a implementação da terapia guiada pela FGx na prática clínica.

Progress in Development of Human Radiolabelled Mass Balance and Biotransformation Studies / 中国药学杂志

Recently, with the rapid development of new drug research in China, the human mass balance and biotransformation (MBB) studies on innovative drugs are on a track to become indispensable during new drug application. However, traditional analysis method, e.g. mass spectrum, is insufficient to elaborately explain the mass balance and the relative biotransformation of the investigated drugs in human bodies. This problem could be solved by applying radiolabelled technique into these MBB studies, which are more and more popular nowadays. The authors' hospital is one of the first a few organizations to conduct the MBB studies, and has completed almost 20 trials. This review mainly focused on the study design from the investigators' viewpoints, involving the related rules and regulations, both at home and abroad, and the protocol design, so as to provide our thinkings for references and benefit to the new drug clinical trial in the future.

Biotransformation and enzymatic mechanism of protoberberine alkaloids / 中国中药杂志

Protoberberine alkaloids belong to the quaternary ammonium isoquinoline alkaloids, and are the main active ingredients in traditional Chinese herbal medicines, like Coptis chinensis. They have been widely used to treat such diseases as gastroenteritis, intestinal infections, and conjunctivitis. Studies have shown that structural modification of the protoberberine alkaloids could produce derivative compounds with new pharmacological effects and biological activities, but the transformation mechanism is not clear yet. This article mainly summarizes the researches on the biotransformation and structure modification of protoberberine alkaloids mainly based on berberine, so as to provide background basis and new ideas for studies relating to the mechanism of protoberberine alkaloids and the pharmacological activity and application of new compounds.

Food Additives and Biotransformation with Cytochrome P450 (CYT P450)

The number of emerging organic and inorganic substances, which are called xenobiotic, is increasing day after day. The potential hazards of these substances are being tested since they are used as drugs and food additives. According to the data obtained from these tests, the harmless ones are released for use. However, it should be noted that these compounds, which are taken as drugs or food additives, are mostly biotransformed with cytochrome P450 in the liver. A large portion of different xenobiotic molecular structures that were biotransformed in the liver can be emptied into the small intestine by a biliary duct and can reenter the organism in their transformed molecular structure. Therefore, it should be accepted that the effects of transformed molecular structures of food additives, especially bread additives, to human must be researched.

Screening and Identification of Lactic Acid Bacteria with D-tagatose Production Capability

Aims: D-tagatose is a natural ketohexose which can be used as a functional sweetener in foods, diary and beverages products. Isolation of new bacterial strains having the ability to produce D-tagatose is a continuously trending topic of research. Study Design: Screening of strains with D-tagatose production by identification and determination of its ability to produce D-tagatose content. Place and Duration of Study: School of Food and Biological Engineering, Jiangsu University between May 2018 and April 2019. Methodology: We initially screened and identified the strains capable of producing D-tagatose through kimchi liquid, and determined the species and genetic characteristics of the strain by physiological, biochemical and molecular biological identification, and then determined the content of D-tagatose by high performance liquid chromatography. Finally calculate the ability of the strain to produce D-tagatose. Results: In this study, 4 strains of lactic acid bacteria (LAB) were isolated from kimchi sample. The isolates were identified as Lactobacillus spp. (Lactobacillus plantarum, Lactobacillus fermentum and Lactobacillus salivarius) on the basis of morphological, physicochemical characteristics and analysis of 16S rDNA gene sequence. Because of the novelty, strain designated as L. salivarius UJS 003 was considered for D-tagatose yield. Fermentation of D-tagatose was carried out using galactose as substrate for 48 hr at 37 °C, and HPLC method was used to determine the yield. The experimental results exhibited a D-tagatose yield of 3.134 g/L by L. salivarius UJS 003. Conclusion: The strain UJS 003 represented as a potent D-tagatose producer and could be useful in a variety of biotechnological and industrial processes, particularly food and beverage industries.

Direct biodegradation of eugenol to coniferyl aldehyde and other higher value-added products by Gibberella fujikuroi ZH-34

BACKGROUND: Eugenol is an economically favorable substrate for the microbial biotransformation of aromatic compounds. Coniferyl aldehyde is one kind of aromatic compound that is widely used in condiment and medical industries; it is also an important raw material for producing other valuable products such as vanillin and protocatechuic acid. However, in most eugenol biotransformation processes, only a trace amount of coniferyl aldehyde is detected, thus making these processes economically unattractive. As a result, an investigation of new strains with the capability of producing more coniferyl aldehyde from eugenol is required. RESULTS: We screened a novel strain of Gibberella fujikuroi, labeled as ZH-34, which was capable of transforming eugenol to coniferyl aldehyde. The metabolic pathway was analyzed by high-performance liquid chromatography­mass spectrometry and transformation kinetics. The culture medium and biotransformation conditions were optimized. At a 6 h time interval of eugenol fed-batch strategy, 3.76 ± 0.22 g/L coniferyl aldehyde was obtained, with the corresponding yield of 57.3%. CONCLUSIONS: This work improves the yield of coniferyl aldehyde with a biotechnological approach. Moreover, the fed-batch strategy offers possibility for controlling the target product and accumulating different metabolites

Influence of gut microbiota regulation on pharmacokinetic characteristics / 中国药学杂志

Intestinal tract plays an important role in the oral drug metabolism, and the gut microbiota which are huge amount and great variety is regard as a vital organs during drug metabolism. The gut micrbiota keep the balance normally, unless some external factors and biological factors change. The changed metabolism of drug would influence the pharmacokinetic characteristics of it. The relevant literatures in recent years about the influence of gut microbiota regulation on pharmacokinetics have been collected in this review, in order to summarize the current research method of pharmacokinetics by gut microbiota and influence of gut microbiota regulation on pharmacokinetics caused by pathologically induced by metabolic disorders, endocrine dyscrasia and insanity, physiology induced by the difference in race and age and drug combination like Chinese traditional medicine, antibiotics and probiotics. This paper not only makes the combination of pathophysiological state and pharmacokinetic characteristics by gut microbiota, but also provides a reference for further research about the influence of gut microbiota regulation on pharmacokinetic characteristics.

Study on preparation, characterization, and transformation of icariin of immobilized snailase on nano-SiO2 / 中草药

Objective: To prepare the immobilized snailase on cross-linked nano-SiO2, characterize its physicochemical properties, and investigate the optimal conditions of hydrolyzing icariin to baohuoside Ⅰ and enzymatic properties. Methods: The snailase was immobilized on the glutaraldehyde cross-linked nano-SiO2 by covalent coupling method. The immobilization conditions were optimized using the relative enzyme activity as the test index. Transmission electron microscopy (TEM), fourier transform infrared spectroscopy (FTIR), and elemental analysis methods were used to characterize the physicochemical properties of immobilized snailase. Using icariin as the substrate and free enzyme as the control, the optimal enzyme conditions, enzymatic kinetic parameters, recyclability, and thermal stability of the immobilized snailase were also investigated. Results: The optimal mass ratio of enzyme to carrier was 1:3 and the optimal immobilization time was 6 h for the preparation of the immobilized snailase. The optimum hydrolysis conditions of the immobilized snailase were as follows: pH 5.0, conversion temperature 60 ℃, mass ratio of enzyme to substrate 1:2, and transformation time 12 h. The Vmax and Km of the immobilized snailase was 0.43 μg/min and 0.78 mmol/L, respectively. After repeated use for 5 times, the residual relative enzyme activity of the immobilized snailase maintained above 70%. Conclusion: The immobilized snailase on cross-linked nano-SiO2 has high mechanical strength, strong stability, and good reusability. It can hydrolyze the icariin to the baohuoside Ⅰ with a better activity. The hydrolysis process was simple, easy, and suitable for industrial production.

Biotransformation of Natural Saponins / 中国实验方剂学杂志

Saponin is a kind of complex compounds with triterpenoid or spiral aglycones.Natural saponins are used as substrates,and many novel compounds are obtained by biotransformation technology. Especially, converted products of saponins with strong activities provide valuable lead compounds for the research and development of new drugs. Saponins can be divided into triterpenoid saponin and steroidal saponin according to the structure of the mother nucleus. There are about 89 reported saponin components,including 56 triterpenoid saponins and 33 steroidal saponins. Biological enzyme catalysis,microbial transformation and intestinal microflora transformation are the main bioconversion technologies and key development directions of saponins. The research and optimization technology of biological enzyme and microbial transformation of saponins are the effective methods to prepare active secondary saponins. The biotransformation reaction of saponins mainly includes hydrolysis,redox and rearrangement,resulting in the formation of aglycones,secondary glycosides and their derivatives. The hydrolysis of saponin sugar chains was the main biological transformation pathway, and could generate a number of secondary saponins with less glycosyl groups. The secondary saponins could be absorbed into blood and become real active ingredients in body. Preparation of rare secondary saponins,discovery of lead compounds and development of new drugs are the main directions of biotransformation of saponins. The studies on the metabolism and mechanism of natural saponins by microbial and intestinal microbial biotransformation will also become hotspots. According to relevant papers at home and abroad,the researches on transformation technique,transformation approach and transformation reaction of saponins from natural products in the past thirty years were summarized, and the prospects of research and development were also analyzed to provide scientific basis for further study and comprehensive utilization of these conversion products.

Study on the Chemical Constituents of Ethyl Acetate Fraction of Panax ginseng Fungal Substance / 中国药房

OBJECTIVE： To study the chemical constituents of ethyl acetate fraction of Panax ginseng fungal substance obtained by biotransformation， in order to obtain compounds with better activity and lower toxicity， and to provide reference for new drug R&D and the second development and utilization of P. ginseng. METHODS： Fungus of Code Name C-1 seed solution was added into the culture medium containing P. ginseng， and P. ginseng fungal substance was obtained by biotransformation； the dried P. ginseng fungal substance were weighed， extracting with 70％ ethanol solvent and concentrating to obtain thick paste. The thick paste was added with water suspension and extracted with ethyl acetate to obtain ethyl acetate fraction. TLC， silica gel column chromatography， ODS column chromatography and semi-prepared liquid phase were used to isolate and purify above ethyl acetate fraction， and the compound structure was identified according to physicochemical properties， hydrogen spectrum （1H-NMR） and carbon spectrum （13C-NMR） data. RESULTS： Eight compounds were isolated and identified from the ethyl acetate fraction of P. ginseng fungal substance and identified as ginsenoside Rs7 （1）， ginsenoside Rk3 （2）， oleanolic acid-28-O-β-D-glucopyranoside （3）， ginsenoside Rs6 （4）， 20（R）-ginsenoside Rh1 （5）， ginsenoside F1 （6）， notoginsenoside R2 （7） and ginsenoside F4 （8）. CONCLUSIONS： All the above compounds were found in P. ginseng fungal substance， which compounds 3， 5， 6， 7 and 8 were obtained after biotransformation， proving that biotransformation technology can change the chemical composition of ginseng.