Changes in the composition and structure of cell wall polysaccharides from Artemisia annua in response to salt stress.

Artemisia annua is cultivated mainly for isolation of artemisinin, a potent antimalarial compound. Moderate salt stress has been proved to increase the artemisinin synthesis by the plant. The aim of this study was to evaluate the influence of salt stress on physiological parameters and cell wall polysaccharides of A. annua. Plants subjected to salt stress displayed reduction in the biomass and length and showed high damage of cellular membranes. Cell wall polysaccharides extracted from aerial parts with hot water, EDTA and NaOH also exhibited modifications in the yield and monosaccharide composition. The main changes were found in the pectic polysaccharides: increase of homogalacturonan domain, increase of neutral side chains and increase in the methyl esterification. 1H NMR analyses of pectins indicated that for A. annua, arabinans have an important role in coping with salt stress. Hemicellulose domain was also modified under salt stress, with increased xylose contents. The results indicated adaptations in the cell wall of A. annua under salt stress.

[Influence of continuous cropping on growth of Artemisia annua and bacterial communities in soil].

In this study, several types of Artemisia annua in soil, including the soil which had not been planted, or planted for one year, or continuously planted for three or five years were collected, in order to study the influences of continuous cropping on the growth of A. annua, content of artemisinin, available nutrient of soil, and bacterial community structure through adopting routine analysis and Illumina MiSeq high-throughput sequencing. The results showed that continuous cropping inhibited significantly the growth of A. annua and reduced leaf biomass, content and yield of artemisinin, with the maximum decreasing amplitude of 30.20%, 7.70% and 35.58% respectively. The content of soil organic matter, available nitrogen, available phosphorus and 16S rRNA sequence number were increased to different extents after continuous cropping of A. annua. According to the results of high-throughput sequencing, 634-812 types of common bacteria belonged to 21 categories were planted in different soil of A. annua with different planting years, which represented that the distribution distance of the point of bacterial community with different years among coordinate system of principal component was relative distant, and community structure had significant changes (P<0.05). As the planting years increased, the abundance of Actinobacteria, Chloroflexi, Gemmatimonadetes decreased in contrast to Proteobacteria, Acidobacteria and Verrucomicrobia. In the top 20 types of predominant bacteria,Nitrospira japonica and Nitrospira disappeared, among which, only Gemmatimonadaceae, Micromonosporaceae, Nitrosomonadaceae, Xanthobacteraceae, and unculture bacterium JG30-KF-AS9 were similar, indicating that the planting and continuous cropping of A. annua selectively inhibited the growth and reproduction of soil bacteria, and influenced the supply and transform of soil nutrient, leading to a poor growth and resulting in reduction of artemisinin content and yield. Therefore, it is necessary to advocate crop rotation in the process of planting A. annua.

[Spatial Distribution and Global Potential Suitability Regions of Artemisia annua].

OBJECTIVE: To study the spatial distribution and potential climatic suitability regions of Artemisia annua around the world. METHODS: The spatial distribution and climatic characteristics were researched by factor analysis based on Global Biodiversity Information Facility Database and World Climate Database. The global potential suitability regions of Artemisia annua were analyzed by ArcGIS. RESULTS: Artemisia annua distributed in three longitude zones, including 90. 55 °W - 77. 14 °W, 2. 03 °E - 11. 75 °E and 98. 27 °E - 111. 05 °E,which were respectively in North America, Europe and Asia. The latitude range was mainly 29. 15 °N - 51. 36 ° N. 80% of Artemisia annua were in the regions which elevation range was 22. 00 - 491. 00 m, annual precipitation was 492. 30 ~ 1 366. 70 mm, annual average temperature was from 8. 10 to 17. 27 °C. The potential suitability regions of Artemisia annua with 95% ~ 100% climate similarity were mainly in 30 °S and 30 °N regions, centered around the equator axis. Conclusion: Latitude is closely related to the distribution of Artemisia annua, the key affecting climatic factors are annual precipitation, the wettest season precipitation, the warmest season precipitation and the highest temperature in the warmest month, the average temperature of the warmest season, as well as the average temperature of the wettest season. The potential suitability regions of Artemnisia annua are in eastern North America, western Europe and eastern Asia.

Type 2C phosphatase 1 of Artemisia annua L. is a negative regulator of ABA signaling.

The phytohormone abscisic acid (ABA) plays an important role in plant development and environmental stress response. Additionally, ABA also regulates secondary metabolism such as artemisinin in the medicinal plant Artemisia annua L. Although an earlier study showed that ABA receptor, AaPYL9, plays a positive role in ABA-induced artemisinin content improvement, many components in the ABA signaling pathway remain to be elucidated in Artemisia annua L. To get insight of the function of AaPYL9, we isolated and characterized an AaPYL9-interacting partner, AaPP2C1. The coding sequence of AaPP2C1 encodes a deduced protein of 464 amino acids, with all the features of plant type clade A PP2C. Transcriptional analysis showed that the expression level of AaPP2C1 is increased after ABA, salt, and drought treatments. Yeast two-hybrid and bimolecular fluorescence complementation assays (BiFC) showed that AaPYL9 interacted with AaPP2C1. The P89S, H116A substitution in AaPYL9 as well as G199D substitution or deletion of the third phosphorylation site-like motif in AaPP2C1 abolished this interaction. Furthermore, constitutive expression of AaPP2C1 conferred ABA insensitivity compared with the wild type. In summary, our data reveals that AaPP2C1 is an AaPYL9-interacting partner and involved in the negative modulation of the ABA signaling pathway in A. annua L.

Effect of irradiated sodium alginate and phosphorus on biomass and artemisinin production in Artemisia annua.

It is now being realized that irradiation products of natural bioactive agents can also be beneficially utilized to impart value addition in agriculture by converting these bioactive agents into more useful form. Polysaccharides, such as sodium alginate, have proven to be wonderful growth promoting substances in their depolymerized form for various plants. Artemisinin has been increasingly popular as an effective and safe alternative therapy against malaria; also proved effective against the highly adaptable malaria parasite, which has already become resistant to many other drugs. The drug artemisinin can be extracted from the leafy tissues of Artemisia annua. Therefore, experiments were conducted with an aim to evaluate artemisinin production and overall plant development though depolymerized sodium alginate application and nutrient supply. In the present study, sodium alginate, irradiated by Co-60 gamma rays together with various phosphorus doses, was used to study their effect on growth, physiological and biochemical processes and production of artemisinin in A. annua. Among various applied doses of phosphorus fertilizer, P40 (40 kg Pha(-1)) together with ISA80 (80 mg L(-1)) significantly improved all the parameters studied. Increase in plant height as well as weight was noted at this treatment. Dry leaf yield, artemisinin concentration in leaves and artemisinin yield was also significantly enhanced by the treatment.

Arsenic, chromium and NaCl induced artemisinin biosynthesis in Artemisia annua L.: a valuable antimalarial plant.

Effect of As(III), Cr(VI) and NaCl on plant growth, antioxidant enzymes, SOD, TBRAS, protein, cDNA amplification of key genes of artemisinin pathway and artemisinin biosynthesis have been investigated to explore the actual changes in total herb and artemisinin yield in a crop cycle of Artemisia annua. Enhanced TBARS and SOD activity (4 U mg⁻¹), decreased catalase activity and total cholorophyll content were observed under metal(loid) and NaCl stress. Accumulation of As (III; µg mg⁻¹ DW) was higher in roots (10.75±0.00) than shoot (0.43±0.00) at 10 µg ml⁻¹. While Cr(VI; µg ml⁻¹ DW) accumulated more in shoots (37±9.6, 41.1±7.2 and 52.71±19.6). cDNA template of these treated plants along with control were amplified with HMGR, ADS and CYP71AV1 genes (artemisinin biosynthetic pathway genes); showed very low expression with Cr(VI) while As(III) (5 and 7.5 µg ml⁻¹) showed higher expression than control. The results obtained from this study suggest that A. annua can grow well with favoring artemisinin biosynthesis with treatment of As(III) 5, 7.5 µg ml⁻¹ and NaCl, while 10 µg ml⁻¹ As(III) and all doses of Cr(VI) affect artemisinin synthesis. Finally some evidence also suggests that As(III), Cr(VI) and NaCl induces stress affects on total herb yield of plant.

[Effect of fertilization on phenolic components and antioxidant activities of Artemisia annua].

OBJECTIVE: A pot experiment with variable fertilizer treatments was carried out to study the influence of fertilization on the concentration and accumulation of polyphenols, scopoletin, chrysosplenol-D and chrysosplenetin in roots, stems and leaves and their antioxidant activities. The main aims were to fertilize scientifically in cultivation of Artemisia annua and improve the quality of the harvest organs. METHOD: These active components in leaves, stems and roots in the squaring stage were analyzed by HPLC and antioxidant activities of the extracts were evaluated by ultraviolet visible light colorimetric method. RESULT: The result showed the highest concentration of polyphenols, scopoletin, chrysosplenol-D and chrysosplenetin was in leaves, followed by stems and the lowest in roots. The antioxidant activities of the leaf extracts correlated positively with the concentrations of polyphenols, scopoletin, chrysosplenol-D and chrysosplenetin. Furthermore, fertilization promoted significantly the growth of A. annua, the biomass was increased by 57.37% (chemical fertilizer), 91.63% (mixture of chemical fertilizer and manure) and 92.27% (manure), respectively, compared to the blank control (without fertilizer). Fertilization, particularly mixture fertilization of chemical fertilizer and manure, increased generally the concentration and accumulation of polyphenols, scopoletin, chrysosplenol-D and chrysosplenetin as well as DPPH x scavenging ratio. CONCLUSION: Scopoletin, chrysosplenol-D and chrysosplenetin could be synthesized and stored mainly in leaves. The leaves might thus be the chief organ of A. annua for medical treatment. Finally, the mixture fertilization of chemical fertilizer and manure should be used to increase the yield and quality of A. annua.

[Determination of artemisinic acid in Artemisia annua at different growth stages based on spot area].

OBJECTIVE: Based on the important medicinal applications of artemisinic acid and the superiority of Thin Layer Chromagraphy (TLC), the spot area method of TLC was presented to determine the content changes of artemisinic acid of Artemisia annua at different growing stages. METHODS: The separation conditions including chromatographic solutions and chromogenic agent were optimized. The detection limit and the linear concentration range were analyzed. And the content changes of artemisinic acid of Artemisia annua at different growing stages were detected. RESULTS: The results showed that artemisinic acid extracted from Artemisia annua could be separated completely by the chromatographic solutions composed by petroleum ether,acetone and ethyl acetate (80: 19: 1). The artemisinic acid was clearly colored using the chromogenic agent consisting by ethanol, bromophenol blue and sulfuric acid. The detection limit of TLC was 0.05 mg/mL. The spot area of TLC had a good linear relationship within the range of 0.05-0.6 mg/mL, accorded with regression equation of y = 11.162 x + 0.0823. The results showed that the content of artemisinic acid at 0.041 mg/g in April which below the detection limit of TLC had no color spot. Contrarily, the spots of artemisinic acid were obvious in materials growing from May to September, and content was about 0.7, 1.2, 2.1, 2.4 and 2.7 mg/g, respectively corresponding to results by HPLC. CONCLUSION: The method can be applied to the quantitative analysis of artemisinic acid in Artemisia annua.

An endophytic Pseudonocardia species induces the production of artemisinin in Artemisia annua.

Endophytic actinobacteria colonize internal tissues of their host plants and are considered as a rich and reliable source of diverse species and functional microorganisms. In this study, endophytic actinobacterial strain YIM 63111 was isolated from surface-sterilized tissue of the medicinal plant Artemisia annua. We identified strain YIM 63111 as a member of the genus Pseudonocardia. A. annua seedlings grown under both sterile and greenhouse conditions were inoculated with strain YIM 63111. The growth of A. annua seedlings was strongly reduced when YIM 63111 was inoculated at higher concentrations under sterile conditions. However, no growth inhibition was observed when A. annua was grown under greenhouse conditions. Using an enhanced green fluorescent protein (EGFP) expressing YIM 63111 strain, we also observed the endophytic colonization of A. annua seedling using confocal laser-scanning microscopy. The transcription levels of the key genes involved in artemisinin biosynthesis were investigated using real time RT-PCR, revealing that cytochrome P450 monooxygenase (CYP71AV1) and cytochrome P450 oxidoreductase (CPR) expression were up-regulated in A. annua upon inoculation with strain YIM 63111 under certain conditions. The up-regulation of these genes was associated with the increased accumulation of artemisinin. These results suggest that endophytic actinobacteria effectively stimulate certain plant defense responses. Our data also demonstrate the use of Pseudonocardia sp. strain YIM 63111 as a promising means to enhance artemisinin production in plants.

[Variation of content of artemisic acid in different growth stages of Artemisia annua].

OBJECTIVE: To study the variation of content of Artemisic acid of Artemisia annua from eight areas of four provinces around Wuling Mountain. METHODS: Artemisic acid of plants were extracted by organic solvent method. Qualitative and quantitative analysis of Artemisic acid were measured by thin layer chromatography (TLC) and high performance thin layer chromatography (HPLC), respectively. RESULTS: The results showed the average levels of Artemisic acid in May and August changed from 0.964 to 2.288 mg/g and from 1.837 to 3.737 mg/g, respectively. The average level in August was 1.5 times as that in May. The Artemisic acid in cultured plants was higher than the levels in wild plants, and Artemisic acid in plant collected below 300 m altitude was higher than that of the plant collected above 300 m altitude. CONCLUSION: The biosynthesis of Artemisic acid depends on the plant growth stage,which is mainly accumulated in plant at the mature stage.

[Effects of inoculating arbuscular mycorrhizal fungi on Artemisia annua growth and its officinal components].

A pot experiment was conducted to study the effects of inoculating arbuscular mycorrhizal (AM) fungi on the growth, nutrient uptake, and officinal components of Artemisia annua. Inoculation with AM fungi Glomus mosseae and G. versiforme improved the uptake of nitrogen, phosphorus, and potassium by A. annua, and increased the leaf chlorophyll content, net photosynthetic rate, stomatal conductance, and transpiration rate as well as the stem diameter and aboveground biomass of A. annua, with greater effects of inoculating G. mosseae than G. versiforme. After the colonization of G. mosseae and G. versiforme, the artemisinin content in A. annua stem, branch, and leaf was increased by 32.8%, 15.2%, and 19.6%, and 26.5%, 10.1%, and 14.9%, and the volatile oil content in leaf was increased by 45.0% and 25. 0%, respectively, compared with the control. Furthermore, mycorrhizal colonization led to changes in volatile components.

[Climate suitable rank distribution of artemisinin content of Artemisia annua in China].

At the urgent request of Artemisia annua (ART) planting, the paper gets artemisinin content (ARTC) of ART in China from literatures. The paper analyses the relationships between ARTC and ecological factors by statistical analytical methods. The paper also analyses the climate suitable rank distribution of ARTC in China by ArcGIS. The results display that first, ARTC is significantly different in China, that ART from the south regions ARTC is higher. Greatest north parts of China have not suitable climate for the growing of ART and the ARTC is lower than 0.2%, when ART grows above the 34th degree of northern latitude. ARTC is higher and ART grows well, when ART grows under the 34 degrees N and grows at the areas between 100 degrees E and 120 degrees E. Second, subtropical zone is the best suitable climate zone for the growing of ART. ART grows well and ARTC is higher than 0.5%, when ART grows in the subtropical zone. Third, temperature, sunshine duration and rainfall are the main ecological factors that affect the growth of ART and the accumulation of ARTC. That the year temperature between 13.9 degrees C and 22 degrees C, sunshine duration between 853 h and 1507 h, rainfall between 814 mm and 1518 mm, is the best climate for the accumulation of ARTC. Temperature between 13 degrees C and 29 degrees C, rainfall between 600 mm and 1300 mm is the best climate for the growth of ART. Fourth, in northwest of Guangxi, eastern of Sichuan, Guizhou and Yunnan provinces, south Chongqing and west Hunan Province, there are suitable climate for the growth of Artemisia and for the accumulating of ARTC. There are also some suitable climate areas for the growing of artemisia in the south of Hubei, Anhui and Jiangsu provinces.

Influencia de las condiciones de cultivo y del momento óptimo de cosecha en Artemisia annua L / Influence of growing conditions and of the optimal harvesting time on Artemisia annua L

Introducción: Artemisia annua L es una planta medicinal de gran interés y es importante precisar los aspectos agrícolas que garanticen su adecuado cultivo. Objetivos: determinar la influencia del cultivo a pleno sol y a la sombra y de la cosecha a diferentes horas y edades de la planta en la producción de biomasa y de los principios activos. Métodos: se utilizaron canteros a plena exposición solar y con determinada disminución de la luz para estudiar las condiciones de cultivo y en las investigaciones del momento de cosecha, en la recolección a diferentes horas del día: 9:00 am, 26 ºC; 11:00 am, 30 ºC; 1:00 pm, 32 ºC; 3:00 pm 33 ºC se seleccionaron plantas cultivadas a pleno sol, de 6 meses de edad; en el otro experimento se evaluó en plantas procedentes de semilleros establecidos en 2 fechas: 5 de noviembre y 8 diciembre, la recolección de la parte aérea a diferentes edades: 5, 6 y 7 meses. Se valoró la producción de biomasa, el contenido de artemisinina y adicionalmente el de aceite esencial y el de alcanfor. La extracción del aceite esencial se realizó por hidrodestilación y la de artemisinina y alcanfor por cromatografía gaseosa, la determinación de la presencia de estos dos componentes se realizó por cromatografía en capa delgada y además se valoraron los parámetros farmacognósticos: sustancias solubles en agua y en alcohol. Resultados: se encontraron pocas diferencias en cuanto al rendimiento de la parte aérea en las dos formas de cultivo, pero sí se obtuvo mayor contenido de artemisinina, aceite esencial y alcanfor en el cultivo a pleno sol. La mejor hora para realizar la cosecha es la mañana...(AU)

Introduction: Artemisia annua L is medicinal plant of great interest, and therefore it is important to specify exactly the agricultural elements supporting its proper growing. Objectives: to determine the influence of growing this plant in the sun and in the shade and of harvesting at different hours and plant ages in the production of biomass and active principles. Methods: flowerbeds were placed in the sun and in dimmed light conditions in order to study the growing conditions. In the research conducted at the time of harvest, plants grown in the sun, of 6 months of age and at various day hours: 9:00 am at 26 ºC; 11:00 am at 30 ºC; 1:00 pm at 32 ºC, and 3:00 pm at 33 ºC were harvested. In the other experiment, the harvest of the aerial parts of the plants coming from seedbeds created on November 5th and on December 8th and aged 5, 6 and 7 months was evaluated. The production of biomass, the content of artemisinin and additionally that of the essential oil and camphor were assessed. The extraction of the essential oil using hydrodistillation and that of artemisinin and the camphor by gas chromatography, the detection of the these two components was made by thin-layer chromatography and also the pharmacognostic parameters such as water- and alcohol-soluble substances were evaluated. Results: there were little differences in aerial parts yielding in the two growing methods but there was high content of artemisinin, essential oil and camphor in plants grown in the sun. The better time interval for harvest is the morning...(AU)

Variation in the volatile constituents of Artemisia annua var. CIM-Arogya during plant ontogeny.

The essential oils yield and composition of the aerial parts of A. annua var. CIM-Arogya grown in Uttarakhand, India were analyzed and compared by capillary GC and GC-MS at different stages of development. The analysis led to the identification of 81 constituents forming 91.0%-97.1% of the essential oils compositions. The essential oil content of the aerial parts was found to vary from 0.3% to 0.7% at different stages of growth. A. annua crop harvested at full flowering and seed setting stage gave higher yield of essential oil (0.6%, 0.7%) than that harvested at pre flowering (0.5%), late vegetative (0.4%, 0.5%), mid vegetative (0.4%, 0.4%) and early vegetative stages (0.3%, 0.3%). The essential oils at different stages of growth showed monoterpenoids (38.5%-72.0%) and sesquiterpenoids (22.2%-48.2%) as major grouped constituents. The major constituents identified were camphor (22.8%-42.6%), 1,8-cineole (3.7%-8.4%), linalool (<0.1%-11.9%), beta-caryophyllene (2.0%-9.2%), (E)-beta-farnesene (1.3%-8.5%), germacrene D (0.5%-7.3%) and 1-epi-cubenol (0.7%-5.2%) in essential oil samples collected at different crop stages.

Influencia de las condiciones de cultivo y del momento óptimo de cosecha en Artemisia annua L / Influence of growing conditions and of the optimal harvesting time on Artemisia annua L

Introducción: Artemisia annua L es una planta medicinal de gran interés y es importante precisar los aspectos agrícolas que garanticen su adecuado cultivo. Objetivos: determinar la influencia del cultivo a pleno sol y a la sombra y de la cosecha a diferentes horas y edades de la planta en la producción de biomasa y de los principios activos. Métodos: se utilizaron canteros a plena exposición solar y con determinada disminución de la luz para estudiar las condiciones de cultivo y en las investigaciones del momento de cosecha, en la recolección a diferentes horas del día: 9:00 am, 26 ºC; 11:00 am, 30 ºC; 1:00 pm, 32 ºC; 3:00 pm 33 ºC se seleccionaron plantas cultivadas a pleno sol, de 6 meses de edad; en el otro experimento se evaluó en plantas procedentes de semilleros establecidos en 2 fechas: 5 de noviembre y 8 diciembre, la recolección de la parte aérea a diferentes edades: 5, 6 y 7 meses. Se valoró la producción de biomasa, el contenido de artemisinina y adicionalmente el de aceite esencial y el de alcanfor. La extracción del aceite esencial se realizó por hidrodestilación y la de artemisinina y alcanfor por cromatografía gaseosa, la determinación de la presencia de estos dos componentes se realizó por cromatografía en capa delgada y además se valoraron los parámetros farmacognósticos: sustancias solubles en agua y en alcohol. Resultados: se encontraron pocas diferencias en cuanto al rendimiento de la parte aérea en las dos formas de cultivo, pero sí se obtuvo mayor contenido de artemisinina, aceite esencial y alcanfor en el cultivo a pleno sol. La mejor hora para realizar la cosecha es la mañana...

Introduction: Artemisia annua L is medicinal plant of great interest, and therefore it is important to specify exactly the agricultural elements supporting its proper growing. Objectives: to determine the influence of growing this plant in the sun and in the shade and of harvesting at different hours and plant ages in the production of biomass and active principles. Methods: flowerbeds were placed in the sun and in dimmed light conditions in order to study the growing conditions. In the research conducted at the time of harvest, plants grown in the sun, of 6 months of age and at various day hours: 9:00 am at 26 ºC; 11:00 am at 30 ºC; 1:00 pm at 32 ºC, and 3:00 pm at 33 ºC were harvested. In the other experiment, the harvest of the aerial parts of the plants coming from seedbeds created on November 5th and on December 8th and aged 5, 6 and 7 months was evaluated. The production of biomass, the content of artemisinin and additionally that of the essential oil and camphor were assessed. The extraction of the essential oil using hydrodistillation and that of artemisinin and the camphor by gas chromatography, the detection of the these two components was made by thin-layer chromatography and also the pharmacognostic parameters such as water- and alcohol-soluble substances were evaluated. Results: there were little differences in aerial parts yielding in the two growing methods but there was high content of artemisinin, essential oil and camphor in plants grown in the sun. The better time interval for harvest is the morning...

[Breeding and spreading of new vairety "Yu-Qing No. 1" of Artemisia annua].

OBJECTIVE: To breed and spread a new cultivar of Artemisia annua. METHOD: The excellent germplasm resources of A. annua in the main production area of Artemisia were collected, and the improved germplasm were screened, the content of artemisinin was determined, and yield per plant was measured. The systematically maternal line and seed production techniques of mass selection were applied combined with the variety test, variety regional test trials and production trials for breeding and spreading the new cultivars of artemisia. RESULT: The popularization and experiment illustrated the production of the new species reached 3 000 kg x hm(-2), compared with wild A. annua it increased 10% -14%. The content of artemisinin reached more than 1%, increased more than 0.2%. CONCLUSION: It is proved that the systematically maternal line and seed production techniques of mass selection can significantly improve the quality of A. annua and it is an acceptable way to cultivate new variety. By production verification, it is practicable and high technical and economic benefits to popularize the new cultivar "Yu-Qing No. 1" of A. annua.

[Correlation and path analysis of artemisininum content and related factor on Artemisiae annie in Three Gorges reservoir area].

OBJECTIVE: Study on the correlation and path analysis of artemisininum comtent and related factor on Artemisiae annie. In order to obtain high artemisininum content Artemisiae annie. METHODS: On the natural condition, choose 36 area where Artemisiae annie growth in three gorges reservoir area. The related factor on artemisininum content are studies through correlation and path analysis. RESULTS: The artemisininum content had significant correlations with biomass, over cover degree, K, P, and N in soil. P in soil had the nost positive influence on the artemisininum content with the direct path coefficinent 0.3439, over cover degree had the nost negative in fluence on the artemisininum content with the direct path coefficient -0.1421. The influence order of other factor was N in soil (0.3180), K in soil (0.2352), biomass ( -0.0084), and plant height (-0.0347). CONCLUSION: Artemisininum content in Artemisiae annie leaves are correlated with biomass, over cover degree, K in soil, P in soil, N in soil.

[Accumulation and translocation of cadmium in soil and plant and its effects on growth of Artemisia annua and artemisinin content].

OBJECTIVE: To study the accumulation and translocation of cadmium in the soil and Artemisia annua, and observe its effects on growth of A. annua and artemisinin content. METHOD: A. annua were cultivated in pots with Cd concentration at 0.5, 1.5, 4.5 mg x kg(-1) level, respectively. RESULT AND CONCLUSION: The growth of A. annua was inhibited at all the Cd levels characterized by the decreases of biomass and agronomic parameters; Most of Cd was accumulated in the roots of A. annua, and the ratios of Cd concentrations in roots and aerial part were 1.8:1 and 2.3:1 at 1.5, 4.5 mg x kg(-1) Cd level, respectively. Artemisinin content increased significant at 0.5 mg x kg(-1) Cd level, but there were no significant changes comparing with control group other Cd levels.

Determinación de la fecha de siembra y del método de plantación de Artemisia annua L introducida en Cuba / Determination of sowing date and the plantation method of Artemisa annua L introduced in Cuba

INTRODUCCIÓN: Artemisia annua L. es una especie originaria de China y Vietnam de interés medicinal para la producción de drogas antipalúdicas, por lo que resulta necesario establecer las condiciones de cultivo en Cuba. OBJETIVO: establecer algunos parámetros agrícolas fundamentales para el cultivo de A. annua. MÉTODOS: se empleó el método de siembra y la fecha de plantación, para lo que se establecieron semilleros en los meses desde diciembre de 2006 a mayo de 2007; posteriormente, a los 2 meses de la siembra, las posturas se trasplantaron a canteros de 1 m de ancho, a pleno sol, y se emplearon 2 variantes: 2 y 3 hileras de plantas y 60 cm de distanciamiento entre plantas, equivalentes a 6 y 9 plantas/m², respectivamente. Para evaluar las mejores variantes las plantas se cosecharon 4 meses después del trasplante, o sea, a la edad de 6 meses; los parßmetros analizados fueron la altura alcanzada en el momento de la cosecha y el rendimiento de follaje fresco. RESULTADOS: solamente se lograron los semilleros que se hicieron en los meses desde diciembre a febrero, con buena germinación, en un período de 10 d. En cuanto al crecimiento y rendimiento se determinó que los mayores valores se observaron en las plantas cultivadas en diciembre y enero y donde se colocaron 3 hileras de plantas/canteros. CONCLUSIONES: esta línea de A. annua introducida en Cuba, adaptada al ambiente tropical vietnamita, bajo las condiciones donde se realizaron los estudios, proporcionó gran adaptabilidad de los semilleros cuando se establecen entre diciembre y enero, así como un crecimiento vigoroso y rendimiento de biomasa adecuada cuando se trasplantan a canteros al sol, con densidad de población de aproximadamente 9 plantas/m², lo que permite hacer su cosecha durante la etapa vegetativa, a los 6 meses de edad, con altos rendimientos de follaje(AU)

INTRODUCTION: Artemisa annua L. is a Vietnam and China-original species of medicinal interest for the anti-paludism drugs begin necessary to establish the culture conditions in Cuba. OBJECTIVE: to establish some fundamental agricultural parameters for A. annua culture. METHODS: we used the sowing method and the plantation date establishing seedbeds from December, 2006 to May, 2007; subsequently at 2 months of sowing, saplings were transplanted to plots of 1 m wide and 60 cm of distance among the plants, equivalent to 6 and 9 plants/m² respectively. To assess the better variants the plants were harvested 4 months after transplantation, that is, at 6 months old; analyzed parameters included the height achieved at the moment of harvest and the fresh foliage yield. RESULTS: we obtained only those seedbeds processed from December to February with a good germination during a period of 10 days. Regards the growth and the yield, we determined that the great values were observed en plants cultured in December and January and where three rows of plants/plots were placed. CONCLUSIONS: this species of A. annua introduced in Cuba and adapted to Vietnamese tropical environment, under conditions where studies were conducted, supplied a big seedbeds adaptation when they are established between December and January, as well as a strong growth and yield of the biomass suitable when seedbeds are transplanted to plots under sunlight, with a population density of approximately 9 plants/m² allowing its harvest during the vegetative stage at 6 months age with high foliage yields(AU)

Enhancement of artemisinin content through four cycles of recurrent selection with relation to heritability, correlation and molecular marker in Artemisia annua L.

Due to the high demand and low yield of the anti-malarial drug artemisinin in natural populations of Artemisia annua (Quinghao), an attempt has been made to enhance the artemisinin content through 4 cycles of recurrent selection (C(0)-C(3)) using selected genotypic and phenotypic traits. Based on their phenotypic and genotypic characteristics, the top 5% plants of each cycle were selected, and their seedlings were planted in poly-cross block to produce seeds for the subsequent generation. A significant increase in the artemisinin content (0.15% in C (0) to 1.16% in C (3), i.e., about 40% genetic gain over the generation) was observed. This enhancement was directly correlated with the plant height and branching intensity in all four cycles. Similarly, the PCV (phenotypic coefficient of variation) and GCV (genotypic coefficient of variation) have been observed to have a higher value for artemisinin content. The DNA marker (MAP 12) with relation to artemisinin was also identified for high yielding genotypes in all four cycles of selection. Over the four cycles of recurrent selection, the plant developed an oval appearance (Variety: CIM-Arogya) and a high artemisinin content (1.16%).