艾纳香内生真菌Diaporthe sp.次生代谢产物

【目的】从艾纳香内生菌J1中获得活性次生代谢产物。【方法】对菌株J1进行ITS序列分子鉴定,综合运用多种色谱技术对其发酵产物进行分离纯化,结合波谱学技术对其进行结构表征。【结果】经构建系统进化树,鉴定菌株J1为Diaporthe sp.,从该菌株大米培养基中分离得到7个单体化合物,经鉴定分别为Dicerandrol A (1)、Dicerandrol B (2)、4,6-dihydroxy-1H-isoindole1,3(2H)-dione (3)、Cytochalasin H (4)、Cytochalasin J (5)、4,6-dihydroxy-2,3-dihydro-1H-isoindol-1-one (6)、Cerebroside C (7)。所有化合物均为首次从该菌中分得,化合物1对枯草芽孢杆菌Bacillus subtilis KCTC 1021具有非常强的抑制活性,MIC值为0.125μg/mL。【结论】Diaporthe sp.富含抑菌活性化合物,具有开发成微生物源农药潜力。     

基于超高效液相色谱-电喷雾-质谱、天然产物词典和活性筛选的艾纳香内生真菌次生代谢产物

【背景】植物内生真菌是天然活性小分子的重要来源,但由于种类繁多,导致寻找结构新颖、活性强的化合物非常困难,重复分离已成为制约新型药源小分子发掘的瓶颈。【目的】综合各种技术,快速寻找目标活性次生代谢产物。【方法】通过对菌株分子鉴定、天然产物词典(dictionaryofnatural products,DNP)数据库检索、超高效液相色谱-电喷雾-质谱(ultraperformanceliquidchromatographyquadrupole time-of-flight mass spectrometry,UPLC-QTof-MS)分析、滤纸片法抑菌实验和色谱技术跟踪获得活性单体化合物。运用质谱和单晶衍射技术对化合物结构进行鉴定,96孔板法对单体化合物进行活性评价。【结果】分离鉴定出11株艾纳香内生真菌,筛选出一株各方面表现良好的艾纳香内生菌菌株Diaporthe sp.,从其大米培养基中获得一个单体化合物Cytochalasin H,活性评价显示其对枯草芽孢杆菌具有很好的抑制活性,MIC值为32μg/mL。【结论】将多种筛选技术相结合的方法应用于艾纳香内生真菌活性代谢产物的发掘,为快速寻找活性先导化合物提供了很好的借鉴。     

药用植物艾纳香基因组DNA提取方法研究

以药用植物艾纳香为研究对象,以-20℃保存、4℃保存、室温自然干燥和硅胶干燥四种样品保存方式,并采用SDS法、CTAB法、SDS-CTAB法和改良CTAB法4种不同的基因组DNA提取方法进行了对比试验,以期建立艾纳香的较好的样品保存方法和基因组DNA提取方法。结果表明,-20℃保存是艾纳香的较理想的样品保存方式;改良CTAB法是艾纳香基因组DNA提取较适宜的方法,该方法提取的DNA经紫外检测,其A_(260)/A_(280)为1.8左右,明显优于SDS法(1.1～1.5)、CTAB法(1.2～1.5)和SDS-CTAB法(1.4～1.6),琼脂糖凝胶电泳、酶切检测和PCR扩增也得出了同样的结论。     

Antibacterial activity of the leaf essential oil of <Emphasis Type="Italic">Blumea mollis</Emphasis> (D. Don) Merr.

The antibacterial activity of the leaf essential oil of Blumea mollis was assayed against 14 clinically isolated bacterial strains on Muller–Hinton Agar medium and Muller–Hinton Agar medium with 5% sheep blood. The essential oil had promising antibacterial activity against all the bacterial strains tested. The highest mean zone of inhibition and lowest values of minimum inhibitory concentration were recorded against methicillin-resistant Staphylococcus aureus followed by beta hemolytic Streptococcus pyogenes. The Gram-positive bacteria were more sensitive than Gram-negative bacteria. Among the bacterial strains tested, Psudomonas aeruginosa was resistant to the essential oil. The results of the present study suggest that the essential oil of B. mollis is one of the new medicinal resources as an antibacterial agent against the bacterial strains tested.     

艾纳香黄酮类化学成分的研究(英文)

从艾纳香(Blumea balsamiferaDC.)的地上部分中分离得到13个黄酮类化合物,经鉴定分别为5,7-二羟基-3,3′,4′-三甲氧基黄酮(1),3,5,3′,4′-四羟基-7-甲氧基黄酮(2),4,2′,4′-三羟基双氢查尔酮(3),儿茶素(4),阿亚黄素(5),davidioside(6),二氢槲皮素-7,4′-二甲醚(7),艾纳香素(8),二氢槲皮素-4′-甲醚(9),3,5,3′-三羟基-7,4′-二甲氧基黄酮(10),5,7,3′,5′-四羟基二氢黄酮(11),木犀草素(12),槲皮素(13)。其中化合物1和3~6为首次从该植物中分离得到。     

NAA处理对艾纳香扦插生根生理生化特性的影响

为探讨NAA对艾纳香(Blumea balsamifera)扦插生根的影响,4 a生艾纳香健康枝条用500 mg/L NAA处理,对生根过程中的生理生化特征进行了研究.结果表明,艾纳香扦插生根率与内源IAA、GA含量和IAA/ABA呈正相关,而与ABA含量呈负相关.NAA处理能提高插穗的IAA含量,降低ABA含量,有助...     

艾纳香内生真菌粉红粘帚霉抗菌次生代谢产物

植物内生真菌一直是发现结构新颖、活性广泛的化合物的重要宝库。文中对一株艾纳香内生真菌粉红粘帚霉Clonostachysrosea进行化学研究,通过活性跟踪手段,结合硅胶柱色谱、凝胶色谱、以及半制备液相色谱技术从该菌株的发酵提取物中共分离获得6个单体化合物,经波谱学技术结合质谱鉴定其分别为verticillin A (1)、(S)-(+)-fusarinolic acid (2)、8-hydroxyfusaric acid (3)、cerebroside C (4)、3-Maleimide-5-oxime (5)以及bionectriol A(6)。所有化合物进行了体外抗大肠埃希菌、金黄色葡萄球菌、枯草芽孢杆菌以及铜绿假单胞菌4株细菌的活性评价,其中1、4和6对3株细菌表现出显著的抑菌活性,MIC值2–16μg/mL。研究结果为从黎药植物艾纳香的内生真菌中寻找新型抗生素提供重要参考。     

Comparative plastome analysis of Blumea,with implications for genome evolution and phylogeny of Asteroideae

The genus Blumea (Asteroideae, Asteraceae) comprises about 100 species, including herbs, shrubs, and small trees. Previous studies have been unable to resolve taxonomic issues and the phylogeny of the genus Blumea due to the low polymorphism of molecular markers. Therefore, suitable polymorphic regions need to be identified. Here, we de novo assembled plastomes of the three Blumea species B. oxyodonta, B. tenella, and B. balsamifera and compared them with 26 other species of Asteroideae after correction of annotations. These species have quadripartite plastomes with similar gene content, genome organization, and inverted repeat contraction and expansion comprising 113 genes, including 80 protein‐coding, 29 transfer RNA, and 4 ribosomal RNA genes. The comparative analysis of codon usage, amino acid frequency, microsatellite repeats, oligonucleotide repeats, and transition and transversion substitutions has revealed high resemblance among the newly assembled species of Blumea. We identified 10 highly polymorphic regions with nucleotide diversity above 0.02, including rps16‐trnQ, ycf1, ndhF‐rpl32, petN‐psbM, and rpl32‐trnL, and they may be suitable for the development of robust, authentic, and cost‐effective markers for barcoding and inference of the phylogeny of the genus Blumea. Among these highly polymorphic regions, five regions also co‐occurred with oligonucleotide repeats and support use of repeats as a proxy for the identification of polymorphic loci. The phylogenetic analysis revealed a close relationship between Blumea and Pluchea within the tribe Inuleae. At tribe level, our phylogeny supports a sister relationship between Astereae and Anthemideae rooted as Gnaphalieae, Calenduleae, and Senecioneae. These results are contradictory to recent studies which reported a sister relationship between “Senecioneae and Anthemideae” and “Astereae and Gnaphalieae” or a sister relationship between Astereae and Gnaphalieae rooted as Calenduleae, Anthemideae, and then Senecioneae using nuclear genome sequences. The conflicting phylogenetic signals observed at the tribal level between plastidt and nuclear genome data require further investigation.