1.Mechanisms of the actions of interferons.
Chinese Journal of Hepatology 2007;15(11):845-846
3.Microbial transformation of artemisinin and its derivatives.
Xin-Na GAO ; Jing-Jie KANG ; Peng SUN ; Yi-Fan ZHAO ; Dong ZHANG ; Lan YANG ; Yue MA ; Hui-Min GAO
China Journal of Chinese Materia Medica 2023;48(11):2876-2895
Microbial transformation is an efficient enzymatic approach for the structural modification of exogenous compounds to obtain derivatives. Compared with traditional chemical synthesis, the microbial transformation has in fact the undoubtable advantages of strong region-and stereo-selectivity, and a low environmental and economic impact on the production process, which can achieve the reactions challenging to chemical synthesis. Because microbes are equipped with a broad-spectrum of enzymes and therefore can metabolize various substrates, they are not only a significant route for obtaining novel active derivatives, but also an effective tool for mimicking mammal metabolism in vitro. Artemisinin, a sesquiterpene with a peroxy-bridged structure serving as the main active functional group, is a famous antimalarial agent discovered from Artemisia annua L. Some sesquiterpenoids, such as dihydroartemisinin, artemether, and arteether, have been developed on the basis of artemisinin, which have been successfully marketed and become the first-line antimalarial drugs recommended by WHO. As revealed by pharmacological studies, artemisinin and its derivatives have exhibited extensive biological activities, including antimalarial, antitumor, antiviral, anti-inflammatory, and immunomodulatory. As an efficient approach for structural modification, microbial transformation of artemisinin and its derivatives is an increasingly popular strategy that attracts considerable attention recently, and numerous novel derivatives have been discovered. Herein, this paper reviewed the microbial transformation of artemisinin and its artemisinin, including microbial strains, culture conditions, product isolation and yield, and biological activities, and summarized the advances in microbial transformation in obtaining active derivatives of artemisinin and the simulation of in vivo metabolism of drugs.
Animals
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Antimalarials/pharmacology*
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Antiviral Agents
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Artemether
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Artemisinins
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Mammals
4.Bioactivity diversity and functional mechanism of tetrahydroisoquinoline alkaloids.
Ce-Jia LIU ; Dian-Yu LIU ; Lan XIANG
Acta Pharmaceutica Sinica 2010;45(1):9-16
Tetrahydroisoquinoline alkaloids distributed widely in the nature and some have a broad application in clinic. More attention has been paid in recent years on this type of alkaloid, owing to the diverse range of biological activities exhibited by these alkaloids and the discovery of new functional mechanisms and molecular targets underlying these activities. This article summarized the recent advances in the biological activities and functional mechanism of tetrahydroisoquinoline, which included the activities such as antitumor, antibiotic, antivirus, anti-inflammatory, anticoagulation, bronchodilation, and the action on central nervous system, with the purpose of providing some ideas in the study of biological activity of this type of alkaloid and in the search for lead-compound and rational drug design.
Animals
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Anti-Inflammatory Agents
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pharmacology
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Anticonvulsants
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pharmacology
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Antifungal Agents
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pharmacology
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Antineoplastic Agents
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pharmacology
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Antiviral Agents
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pharmacology
;
Bronchodilator Agents
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pharmacology
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Central Nervous System Agents
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pharmacology
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Fibrinolytic Agents
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pharmacology
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Humans
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Neuroprotective Agents
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pharmacology
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Tetrahydroisoquinolines
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chemical synthesis
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chemistry
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pharmacology
5.The recent advances in the host targets of anti-influenza drugs.
Lin-Lin MA ; Jian-Dong JIANG ; Yu-Huan LI
Acta Pharmaceutica Sinica 2014;49(12):1631-1638
The challenge of the emergence of drug-resistant influenza strains, which is caused by wide spread utilization of direct-acting antivirals (DAAs), accelerates the research and exploration towards host targeted agents. In contrast to DAAs targeting viral replication components, host targeted agents, which regulate host factors and pathways linked to viral replication, can interfere the replication of influenza. Additionally, the innate immune system is activated by influenza during the early stage of infection, so manipulating the innate immune response may prevent the viral infection. However, the excessive inflammatory response induced at the late phase of influenza infection would lead to severe tissue injures. Thus, it is very important to explore drugs with anti-inflammatory actions to suppress these immune imbalances and tissue injures. Here we overview the current progresses about host targets related to anti-influenza drugs.
Anti-Inflammatory Agents
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pharmacology
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Antiviral Agents
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pharmacology
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Humans
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Immunity, Innate
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Influenza, Human
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drug therapy
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Virus Replication
7.Reviews on antiviral activity of chemical constituents from plants.
Xian-Feng YANG ; Yu-Li WANG ; Wei-Ren XU
China Journal of Chinese Materia Medica 2008;33(1):100-104
This paper reviewed the progress in researches on antiviral activity of chemical constituents from plants in recent years, the antiviral activity and mechanism of action of flavonoids, alkaloids, terpenoids, coumarins and polysaccharoses were sammarszed, provided new leading compound for antivirus new drugs from the plares in prospect.
Antiviral Agents
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chemistry
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pharmacology
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Drugs, Chinese Herbal
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chemistry
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pharmacology
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Molecular Structure
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Plant Extracts
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chemistry
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pharmacology
8.Construction of the recombinant adenovirus carrying porcine interferon gamma (poIFNgamma) and identification of its antiviral activity.
Qing-Xia YAO ; Zhuo-Fei XU ; Yan-Nan HE ; You-Hui SI ; Ping QIAN ; Huan-Chun CHEN
Chinese Journal of Virology 2007;23(5):394-398
The total RNA was extracted from peripheral blood mononuclear cells (PBMC) which was isolated from Meishan porcine and induced with concanavaline A (ConA), then the porcine interferon gamma gene (PoIFNgamma, 501bp) was amplified by RT-PCR. The result of sequencing demonstrated that the amplified PoIFNgamma had 100% nucleotide homology with the other porcine IFNgamma sequence published on GenBank. The objective gene (PoIFNgamma) was inserted into adenoviral shuttle vector, pShuttle-CMV, to construct recombinant plasmid pSh-PoIFNgamma. And it was co-electrotransformated with adenoviral skeletal vector pAdEasy-1 into competent cells of BJ5183. The transforms were cultured at 37 degrees C for 24h on kanamycin resistance plate and selected for smaller colonies. Then, the extracted recombinant plasmid was named pAd-Sh-PoIFNgamma, which was confirmed by Pac I digestion, and transformed into XL10-Glod(r) for copious preparation. pAd-Sh-PoIFNgamma linearized with Pac I was co-transfected with liposome into 293 package cell-line. After 7d-10d, the typical cytopathic effect indicated that recombinant adenoviral genome (deleted with E1 and E3 genes) carrying PoIFNgamma was successfully packaged into intact virion. The recombinant virion was successively seeded to the 10th generation and the viral genome was extracted from each generation by PCR. The antiviral activity of PoIFNgamma was tested by CPE50 method. The results showed that the PoIFNgamma expressed by adenovirus had high antiviral activity, which was 1.3 x 10(6) U/mL against VSV in MDBK cells. The results demonstrated that the recombinant adenovirus carrying PoIFNgamma could be stably passaged.
Adenoviridae
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genetics
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Animals
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Antiviral Agents
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pharmacology
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Interferon-gamma
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genetics
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pharmacology
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Recombinant Proteins
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biosynthesis
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pharmacology
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Swine
9.Recombinant porcine interferon-gamma expressed in CHO cells and its antiviral activity.
Lingyun WANG ; Rongzeng HAO ; Yang YANG ; Yajun LI ; Bingzhou LU ; Yuhan MAO ; Yue ZHANG ; Zhenli GONG ; Yanhong LIU ; Meng QI ; Yi RU ; Haixue ZHENG
Chinese Journal of Biotechnology 2023;39(12):4784-4795
The aim of this study was to produce recombinant porcine interferon gamma (rPoIFN-γ) by Chinese hamster ovarian (CHO) cells expression system and to analyze its antiviral activity. Firstly, we constructed the recombinant eukaryotic expression plasmid pcDNA3.1-PoIFN-γ and transfected into suspension cultured CHO cells for secretory expression of rPoIFN-γ. The rPoIFN-γ was purified by affinity chromatography and identified with SDS-PAGE and Western blotting. Subsequently, the cytotoxicity of rPoIFN-γ was analyzed by CCK-8 test, and the antiviral activity of rPoIFN-γ was evaluated using standard procedures in VSV/PK-15 (virus/cell) test system. Finally the anti-Seneca virus A (SVA) of rPoIFN-γ activity and the induction of interferon-stimulated genes (ISGs) and cytokines were also analyzed. The results showed that rPoIFN-γ could successfully expressed in the supernatant of CHO cells. CCK-8 assays indicated that rPoIFN-γ did not show cytotoxicity on IBRS-2 cells. The biological activity of rPoIFN-γ was 5.59×107 U/mg in VSV/PK-15 system. Moreover, rPoIFN-γ could induced the expression of ISGs and cytokines, and significantly inhibited the replication of SVA. In conclusion, the high activity of rPoIFN-γ was successfully prepared by CHO cells expression system, which showed strong antiviral activity on SVA. This study may facilitate the investigation of rPoIFN-γ function and the development of novel genetically engineered antiviral drugs.
Swine
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Animals
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Cricetinae
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Interferon-gamma/pharmacology*
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Cricetulus
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CHO Cells
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Sincalide
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Recombinant Proteins/pharmacology*
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Antiviral Agents/pharmacology*
10.Distribution of lamivudine- resistant variants in hepatitis B virus.
Guan-guan SU ; Dan-hong YANG ; Nian-feng ZHAO
Journal of Zhejiang University. Medical sciences 2003;32(4):349-358
OBJECTIVETo observe the distribution of HBV variants resistant to lamivudine and their relation to clinical manifestations of chronic hepatitis.
METHODSUsing direct sequencing, YMDD (tyrosine-methionine-aspartate-aspartate) variants in patients with chronic HBV were detected before and during treatment with lamivudine. A statistical analysis of the distribution of HBV strains resistant to lamivudine was performed.
RESULTFour variant strains existed in patients before lamivudine treatment, 128 variant resistant strains were noted after 6 mouths of lamivudine treatment including 42 YVDD (valine) variants, 20 YIDD (isoleusine) variants and 66 non-YMDD variants. According to the hepatitis severity, 8 patients were mild, 108 moderate and 12 severe. Viral loading was higher and clinical types were more severe in no-YMDD variants.
CONCLUSIONVariant strains including strains resistant to lamivudine exist naturally before lamivudine treatment, but lamivudine-resistant ones become more dominant after treatment. Liver inflammation is more severe in non-YMDD group.
Antiviral Agents ; pharmacology ; Drug Resistance, Viral ; Genetic Variation ; Hepatitis B virus ; drug effects ; genetics ; Lamivudine ; pharmacology