红枣活性成分及其生物活性研究进展

红枣中的活性成分以多糖、黄酮类、环核苷酸类、多酚类、五环三萜类、生物碱为主,具有抗氧化、免疫调节及抗肿瘤、保护肝脏、降血糖、抗炎等多种生物活性。本文综述了红枣中活性成分及生物活性的研究进展,并对红枣产业的发展进行展望,为红枣中活性成分的开发与利用提供科学依据。     

山橙属植物化学成分与抗肿瘤活性研究进展

结合国内外文献综述了山橙属植物化学成分的研究进展,并对该属药用植物的抗肿瘤活性进行了总结。山橙属植物含有多种化学成分,主要有生物碱类以及少量三萜类、甾体类、木脂素类等。该属植物中的生物碱类成分具有显著的抗肿瘤活性。     

海金沙的化学成分和药理活性研究进展

海金沙是海金沙科海金沙属多年生蕨类植物,在我国广东、海南、江苏、浙江等地广泛分布。海金沙含有黄酮类化合物、酚酸及其糖苷类化合物及三萜类化合物等多种生物活性成分,具有利胆、防治结石、抗氧化、抗茵等多种药理活性。对海金沙的化学成分和药理活性做了综述,以便更好地对其进行开发利用。     

山橙属植物化学成分与抗肿瘤活性研究进展北大核心CSCD

结合国内外文献综述了山橙属植物化学成分的研究进展,并对该属药用植物的抗肿瘤活性进行了总结。山橙属植物含有多种化学成分,主要有生物碱类以及少量三萜类、甾体类、木脂素类等。该属植物中的生物碱类成分具有显著的抗肿瘤活性。     

《基因组生物学》:科学家破译芝麻抗衰老功能密码

发表在国际专业刊物《基因组生物学》的文章称,中国农业科学院油料作物研究所与深圳华大基因联合开展的芝麻基因组破译工作近日顺利完成。这项研究分析了芝麻高含油量和特有抗氧化、抗衰老功能性成分芝麻素的形成机制。据项目主持人张秀荣介绍,芝麻油保存期明显长于其他食用油,原因在于芝麻中含有特殊物质芝麻素。芝麻素具有很强的抗氧化性,能够增加油质的稳定性,临床已证实芝麻素具有治疗癌症及心血管疾病等功效。科研团队通过比较基因组研究发现,芝麻素合成关键基因仅存在芝麻     

大血藤化学成分及药学研究进展

目的:对传统中药大血藤的化学成分及药学研究概况进行综述.方法:查阅国内外发表的文献为依据.结果:传统中药大血藤中含有鞣质、糖苷、环多酚类、三萜皂甙类、木质素类、黄酮类、甙类及有机酸类等多种化学成分;药理研究证明,其具有抗辐射;抗菌、抗炎、抗急,陛过敏、抗癌及心血管系统活性等作用,结论:大血藤具有多种药理活性,有希望从中开发出治疗心血管疾病和抗炎的现代药物.对其进行进一步的研究和开发具有重要意义.     

磺胺比色法测定植物组织硝酸还原酶活性的改进

“植物组织硝酸还原酶（NR）活性的测定”是植物生理学矿质营养一章中必做的实验,其目的是让学生掌握植物硝酸还原酶（nitrate reductase,NR,EC．1．6．6．1）活性测定的原理和技术方法,进一步了解NR在植物氮素同化过程中的作用（白宝璋和汤学军1993;李合生等2001;郝建军等2007）。但是,在实验教学中,我们感到,按照几种植物生理学实验指导书中介绍的方法（白宝璋和汤学军1993;李合生等2001;     

后连合核及其形态学和电生理学研究进展

后连合核位于腰骶尾髓的脊髓灰质后连合 ,含丰富的神经活性物质 ,并表达多种神经递质受体 ,与中枢及外周联系广泛 ,在功能上与内脏感觉的中继、内脏和躯体初级传入信息的整合、镇痛及内脏反射活动等密切相关。一些内源性物质可能通过对兴奋性及抑制性神经递质的作用 ,参与对后连合核信息传递的调控。本文对后连合核及其形态学和电生理学研究进展作一综述     

卷柏属植物化学成分及药理活性研究进展

卷柏属植物含有黄酮类、炔酚类、苯丙素类等多种化学成分。药理学研究证明该属植物具有抗肿瘤、抗炎、抗氧化、抗菌抗病毒等药理活性。本文系统地介绍了国内外对卷柏属植物化学成分和药理活性方面的研究概况,为今后对该属植物的进一步研究提供参考。     

猪牙皂的化学成分和药理活性研究进展

猪牙皂主要含有多种三萜皂苷,具有抗炎、抗过敏、抗肿瘤、抗病毒、改善心肌缺血等药理活性。就近年来的研究成果作一综述,为猪牙皂的进一步开发和利用提供科学依据。     

Transesterified sesame (Sesamum indicum L.) seed oil as a biodiesel fuel

The sesame (Sesamum indicum L.) oil was extracted from the seeds of the sesame that grows in Diyarbakir, SE Anatolia of Turkey. Sesame seed oil was obtained in 58wt/wt%, by traditional solvent extraction. The methylester of sesame (Sesamum indicum L.) seed oil was prepared by transesterification of the crude oil. Transesterification shows improvement in fuel properties of sesame seed oil. This study supports the production of biodiesel from sesame seed oil as a viable alternative to the diesel fuel.     

Tolerant and Susceptible Sesame Genotypes Reveal Waterlogging Stress Response Patterns

Waterlogging is a common adverse environmental condition that limits plant growth. Sesame (Sesamum indicum) is considered a drought-tolerant oil crop but is typically susceptible to harmful effects from waterlogging. The present study used comparative analysis to explore the waterlogging stress response associated with two sesame genotypes. The RNA-seq dataset generated during a time course of 0, 3, 9 and 15 h of waterlogging as well as 20 h post-drainage indicated that stress gradually suppressed the expression of sesame genes, with 9 h as the critical time point for the response of sesame to waterlogging stress. Of the 19,316 genes expressed during waterlogging, 72.1% were affected significantly. Sesame of both tolerant and susceptible genotypes showed decreased numbers of upregulated differentially expressed genes (DEGs) but increased numbers of downregulated DEGs at the onset of waterlogging. However, the tolerant-genotype sesame exhibited 25.5% more upregulated DEGs and 29.7% fewer downregulated DEGs than those of the susceptible-genotype strain between 3 and 15 h. The results indicated that the tolerant sesame displayed a more positive gene response to waterlogging. A total of 1,379 genes were significantly induced and commonly expressed in sesame under waterlogging conditions from 3 to 15 h regardless of tolerance level; of these genes, 98 are known homologous stress responsive genes, while the remaining 1,281 are newly reported here. This gene set may represent the core genes that function in response to waterlogging, including those related mainly to energy metabolism and phenylpropanoid biosynthesis. Furthermore, a set of 3,016 genes functioning in energy supply and cell repair or formation was activated in sesame recovery from waterlogging stress. A comparative analysis between sesame of the tolerant and susceptible genotypes revealed 66 genes that may be candidates for improving sesame tolerance to waterlogging. This study provided a comprehensive picture of the sesame gene expression pattern in response to waterlogging stress. These results will help dissect the mechanism of the sesame response to waterlogging and identify candidate genes to improve its tolerance.     

Incidence and severity of foliar diseases of sesame (Sesamum indicum L.) intercropped with maize (Zea mays L.)

This study evaluates the effects of different row arrangements on incidence and severity of Cercospora leaf spot (CLS) and Alternaria leaf blight (ALB) diseases and seed health of sesame intercropped with maize. Row arrangements were: sesame intercropped with maize in alternate pair of rows (2:2), two rows of sesame intercropped with one row of maize (2:1), sesame intercropped with maize in single alternate rows (1:1) with sole sesame as control. Intercropping maize with sesame reduced the incidence and severity of diseases. Sesame intercropped with maize in a (1:1) ration recorded a significantly lower number of infected leaves by CLS and ALB incidence than other row arrangements. ALB lesion number was between 17 and 20 in the (1:1) arrangement relative to 65–104 and 28–43 in the sole crop and other row arrangements, respectively. ALB lesion size was also reduced in the (1:1) than other row arrangements. Fungal infection of harvested sesame seeds was significantly reduced in the intercrop relative to the sole crop. CLS incidence was significant and negatively correlated with seed weight while defoliation was significant and positively correlated with ALB or CLS incidence. Rainfall was significant and positively correlated with CLS or ALB incidence while intercropping induced microclimatic effects that influenced disease incidence. Grain yield, weight of 1000-seed, number of capsules/plant and weight of seed/plant were significantly higher in the (1:1) row arrangement than the sole crop or other row arrangements. The study demonstrates that intercropping sesame with maize in a single alternate row (1:1) arrangement can be used to reduce foliar diseases of sesame.     

Sesame genotype influences growth and phenology of Phelipanche aegyptiaca

Egyptian broomrape (Phelipanche aegyptiaca) is a parasitic weed causing major yield loss in many field and vegetable crops. Recent observations in Iran suggest that sesame (Sesamum indicum) may serve either as a trap crop or as a host for broomrape, depending on genotype. The central objective of this research was to identify sesame genotypes that could act either as potential trap crops, or sources of genetic material for development of broomrape resistant cultivars. Seeds of 11 Iranian sesame genotypes (Ardestan, Esfarayen, Oltan, Ahvaz, Borazjan, Darab‐14, Ferdous, Kalat, Naz Tak Shakhe, Varamin and Yekta) and 10 foreign genotypes (S16, S21, S23, S25, S4, S5, S6, S7, S8 and S9) were planted with broomrape seeds in pots. At the flowering stage of sesame, tubercle number and dry weight, shoot number and dry weight and shoot height of broomrape were determined. Shoot dry weight, root dry weight and seed yield of sesame were determined at the physiological maturity. The results showed that broomrape growth varied with sesame genotype. Egyptian broomrape dry weight measured from 1.6% (S23) to 35.4% (Kalat) of the dry weight of the sesame on which it grew. Broomrape total dry weight had positive and highly correlation with the root dry weight of the sesame genotype on which it grew. When broomrape planted with the S7, S8, S9, S21 and S23 genotypes produced tubercles, but no shoots on these genotypes. Such genotypes could be used as both trap crops and as breeding‐sources for development of resistant sesame genotypes.     

Identification of sesame (Sesamum indicum L.) chromosomes using the BAC‐FISH system

• Sesame (Sesamum indicum L.; Pedaliaceae) is a commercially valuable oilseed crop with high oil content. Its small genome size favours the genomic analysis of key biological processes, such as oil synthesis and metabolism. However, the 13 chromosome pairs of sesame have not been characterised because of technological limitations and their small size.
• We constructed a BAC library comprising 57,600 BAC clones for sesame. The estimated genome coverage of the sesame BAC library was 13.8×. The successive double colour fluorescence in situ hybridisation (FISH) with bacterial artificial chromosomes (BACs) for sesame was established in this study.
• Subsequently, the 13 sesame chromosome pairs were individually differentiated using 17 specific BACs for the first time. The schematic of the sesame chromosome set was drawn according to the chromosome relative length and relative position of the BAC signal. The cytogenetic characteristics of sesame chromosomes were also explored.
• The results provide the technical background required for further cytogenetic map construction, genome assembly and localisation of the DNA sequence in sesame.

     

Etiology and Transmission of Sesame Phyllody in Iran

Phyllody is a destructive disease of sesame (Sesamum indicum L.) in Iran. The major symptoms of the disease are floral virescence, phyllody and proliferation. Other symptoms which sometimes accompany the disease are yellowing, cracking of seed capsules, germination of seeds in the capsules and formation of dark exudates on the foliage. Light microscopy of hand-cut sections of sesame and colza (Brassica napus L. cv. Oro) stems treated with Dienes' stain showed blue areas in the phloem region of phyllody infected plants. Mycoplasma-like bodies were found in the sieve cells of infected sesame stems when thin sections were examined m an electron microscope. Sesame phyllody was successfully transmitted from sesame to sesame by grafting. Among various leafhoppers collected in sesame fields only Neoaliturus haematoceps transmitted the disease. This is the first report on the identification of a Mycoplasma-like organism (MLO) as the cause of sesame phyllody and N. haematoceps as an MLO vector in Iran. In host range studies using the leafhopper vector, only B. napus cv. Oro, Lepidium sativum, Catharanthus roseus, Lactuca sp. and Portulaca oleracea, but not 17 other species, developed symptoms. The species of vector and host range of MLO indicate that sesame phyllody in Iran is different from that reported in India and Upper Volta.     

Effect of sesame oil on diuretics or Beta-blockers in the modulation of blood pressure, anthropometry, lipid profile, and redox status

The study was undertaken to investigate the effect of sesame oil in hypertensive patients who were on antihypertensive therapy either with diuretics (hydrochlorothiazide) or ß-blockers (atenolol). Thirty-two male and 18 female patients aged 35 to 60 years old were supplied sesame oil (Idhayam gingelly oil) and instructed to use it as the only edible oil for 45 days. Blood pressure, anthropometry, lipid profile, lipid peroxidation, and enzymic and non-enzymic antioxidants were measured at baseline and after 45 days of sesame oil substitution. Substitution of sesame oil brought down systolic and diastolic blood pressure to normal. The same patients were asked to withdraw sesame oil consumption for another 45 days, and the measurements were repeated at the end of withdrawal period. Withdrawal of sesame oil substitution brought back the initial blood pressure values. A significant reduction was noted in body weight and body mass index (BMI) upon sesame oil substitution. No significant alterations were observed in lipid profile except triglycerides. Plasma levels of sodium reduced while potassium elevated upon the substitution of sesame oil. Lipid peroxidation (thiobarbituric acid reactive substances [TBARS]) decreased while the activities of superoxide dismutase (SOD), catalase (CAT), and the levels of vitamin C, vitamin E, ß-carotene, and reduced glutathione (GSH) were increased. The results suggested that sesame oil as edible oil lowered blood pressure, decreased lipid peroxidation, and increased antioxidant status in hypertensive patients.     

Identification of a characteristic antioxidant,anthrasesamone F,in black sesame seeds and its accumulation at different seed developmental stages

Assay-guided fractionation of the methanol extract from black seeds of sesame (Sesamum indicum L.) led to the isolation of an active compound that had a 1,1-diphenyl-2-picrylhydrazyl radical scavenging activity. This antioxidant was confirmed to be anthrasesamone F, an anthraquinone derivative previously isolated from different black sesame seeds and biogenetically related to other anthrasesamones in sesame roots. The radical scavenging assay showed that anthrasesamone F had more potent activity than Trolox. The content of anthrasesamone F in different parts and at different developmental stages of black sesame seeds was investigated to clarify the accumulation pattern of this antioxidant in the black seeds. Anthrasesamone F was localized in the seed coat of black seeds and accumulated after the seed coat color changed to black. The content of anthrasesamone F increased gradually with seed maturation and drastically on air-drying, the final stage in sesame cultivation.     

Insight into the evolution and functional characteristics of the pan‐genome assembly from sesame landraces and modern cultivars

Sesame (Sesamum indicum L.) is an important oil crop renowned for its high oil content and quality. Recently, genome assemblies for five sesame varieties including two landraces (S. indicum cv. Baizhima and Mishuozhima) and three modern cultivars (S. indicum var. Zhongzhi13, Yuzhi11 and Swetha), have become available providing a rich resource for comparative genomic analyses and gene discovery. Here, we employed a reference‐assisted assembly approach to improve the draft assemblies of four of the sesame varieties. We then constructed a sesame pan‐genome of 554.05 Mb. The pan‐genome contained 26 472 orthologous gene clusters; 15 409 (58.21%) of them were core (present across all five sesame genomes), whereas the remaining 41.79% (11 063) clusters and the 15 890 variety‐specific genes were dispensable. Comparisons between varieties suggest that modern cultivars from China and India display significant genomic variation. The gene families unique to the sesame modern cultivars contain genes mainly related to yield and quality, while those unique to the landraces contain genes involved in environmental adaptation. Comparative evolutionary analysis indicates that several genes involved in plant‐pathogen interaction and lipid metabolism are under positive selection, which may be associated with sesame environmental adaption and selection for high seed oil content. This study of the sesame pan‐genome provides insights into the evolution and genomic characteristics of this important oilseed and constitutes a resource for further sesame crop improvement.