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中国科学院昆明植物研究所知识管理系统
Knowledge Management System of Kunming Institute of Botany,CAS
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0.05) between wild (AR = 4.651), semi-cultivated (AR = 5.091) and cultivated (AR = 5.132) populations of C. taliensis, which suggested that the genetic background of long-lived woody plant was not easy to be changed, and there were moderate high gene flow between populations. However, there was a significant difference (P < 0.05) between wild (AR = 5.9) and cultivated (AR = 7.1) populations distributed in the same place in Yun county, Yunnan province, which may result from the hybridization and introgression of species in the tea garden and anthropogenic damages to the wild population. The hypothesis of hybrid origin of C. grandibracteata was tested by morphological and microsatellites analyses. Compared with other species, the locules in ovary of C. grandibracteata are variable, which showed a morphological intermediate and mosaic. Except one private allele, Ninety-nine percent alleles of C. grandibracteata were shared with these of C. taliensis and C. sinensis var. assamica. And C. grandibracteata was nested in the cluster of C. taliensis in the UPGMA tree. Conclusively, our results supported the hypothesis of hybrid origin of C. grandibracteata partly. The speciation of C. grandibracteata was derived from hybridization and asymmetrical introgression potentially. It is possible that C. taliensis was one of its parents, but it still needs more evidences to prove that C. sinensis var. assamica was another parent.","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ACamellia%5C+taliensis%5C+%5C%28W.%5C+W.%5C+Smith%5C%29%5C+Melchior%2C%5C+a%5C+member%5C+of%5C+Camellia%5C+sect.%5C+Thea%2C%5C+is%5C+an%5C+indigenous%5C+species%5C+in%5C+local%5C+natural%5C+forest%5C+and%5C+has%5C+a%5C+long%5C+cultivative%5C+history%5C+in%5C+western%5C+Yunnan%5C+and%5C+its%5C+neighborhood%2C%5C+where%5C+the%5C+domestications%5C+of%5C+this%5C+species%5C+in%5C+different%5C+historical%5C+periods%5C+and%5C+in%5C+different%5C+ways%5C+can%5C+be%5C+found.%5C+C.%5C+taliensis%5C+is%5C+an%5C+important%5C+contributor%5C+to%5C+the%5C+formations%5C+of%5C+tea%5C+landraces%5C+by%5C+hybridization%5C+and%5C+introgression.%5C+In%5C+the%5C+present%5C+study%2C%5C+14%5C+microsatellite%5C+loci%5C+screened%5C+from%5C+37%5C+loci%5C+were%5C+used%5C+to%5C+explore%5C+the%5C+genetic%5C+diversity%5C+about%5C+this%5C+species%5C+with%5C+579%5C+samples%5C+from%5C+25%5C+populations%5C+%5C%2816%5C+wild%5C+populations%2C%5C+4%5C+semi%5C-cultivated%5C+populations%5C+and%5C+5%5C+cultivated%5C+populations%5C%29.%5C+At%5C+the%5C+same%5C+time%2C%5C+the%5C+potential%5C+hybrid%5C+speciation%5C+of%5C+C.%5C+grandibracteata%2C%5C+was%5C+investigated%5C+using%5C+39%5C+individuals%5C+from%5C+2%5C+populations%2C%5C+along%5C+with%5C+C.%5C+taliensis%5C+and%5C+C.%5C+sinensis%5C+var.%5C+assamica%5C+%5C%2883%5C+individuals%5C+from%5C+4%5C+populations%5C%29%5C+by%5C+the%5C+same%5C+microsatellite%5C+markers.%5C+C.%5C+taliensis%5C+had%5C+a%5C+moderate%5C+high%5C+level%5C+of%5C+genetic%5C+diversity%5C+%5C%28A%5C+%3D%5C+14.3%2C%5C+Ne%3D%5C+5.7%2C%5C+HE%5C+%3D%5C+0.666%2C%5C+I%5C+%3D%5C+1.753%2C%5C+AR%5C+%3D%5C+7.2%2C%5C+PPB%5C+%3D%5C+100%25%5C%29.%5C+This%5C+may%5C+result%5C+from%5C+several%5C+factors%5C+including%5C+K%5C-strategy%2C%5C+genetic%5C+background%2C%5C+gene%5C+flow%5C+between%5C+populations%2C%5C+hybridization%5C+and%5C+introgression%5C+among%5C+species.%5C+Between%5C+wild%5C+populations%5C+of%5C+C.%5C+taliensis%2C%5C+the%5C+gene%5C+flow%5C+was%5C+moderate%5C+high%5C+%5C%28Nm%5C+%3D%5C+1.197%5C%29%2C%5C+and%5C+genetic%5C+variation%5C+was%5C+less%5C+than%5C+20%25%5C+%5C%28GST%5C+%3D%5C+0.147%2C%5C+FST%5C+%3D%5C+0.173%5C%29%2C%5C+which%5C+was%5C+similar%5C+to%5C+other%5C+research%5C+results%5C+of%5C+long%5C-lived%5C+woody%5C+plants%2C%5C+and%5C+reflected%5C+the%5C+genetic%5C+structure%5C+of%5C+its%5C+ancestry%5C+to%5C+same%5C+extent.%5C+There%5C+was%5C+a%5C+high%5C+significant%5C+correlation%5C+between%5C+geographic%5C+distance%5C+and%5C+Nei%E2%80%99s%5C+genetic%5C+distance%5C+%5C%28r%5C+%3D%5C+0.372%2C%5C+P%5C+%3D%5C+0.001%5C%29%5C+of%5C+populations%2C%5C+which%5C+accorded%5C+with%5C+isolation%5C+by%5C+distance%5C+model.%5C+Inferring%5C+from%5C+Bayesian%5C+clustering%5C+of%5C+genotypes%2C%5C+all%5C+individuals%5C+of%5C+C.%5C+taliensis%5C+were%5C+divided%5C+into%5C+two%5C+groups%2C%5C+conflicting%5C+with%5C+the%5C+result%5C+based%5C+on%5C+Nei%E2%80%99s%5C+genetic%5C+distance%5C+and%5C+real%5C+geographic%5C+distribution%2C%5C+which%5C+suggested%5C+there%5C+were%5C+heavy%5C+and%5C+non%5C-random%5C+influences%5C+by%5C+human%5C+practices.%5C+According%5C+to%5C+allelic%5C+richness%2C%5C+there%5C+were%5C+no%5C+significant%5C+differences%5C+%5C%28P%5C+%3E%5C+0.05%5C%29%5C+between%5C+wild%5C+%5C%28AR%5C+%3D%5C+4.651%5C%29%2C%5C+semi%5C-cultivated%5C+%5C%28AR%5C+%3D%5C+5.091%5C%29%5C+and%5C+cultivated%5C+%5C%28AR%5C+%3D%5C+5.132%5C%29%5C+populations%5C+of%5C+C.%5C+taliensis%2C%5C+which%5C+suggested%5C+that%5C+the%5C+genetic%5C+background%5C+of%5C+long%5C-lived%5C+woody%5C+plant%5C+was%5C+not%5C+easy%5C+to%5C+be%5C+changed%2C%5C+and%5C+there%5C+were%5C+moderate%5C+high%5C+gene%5C+flow%5C+between%5C+populations.%5C+However%2C%5C+there%5C+was%5C+a%5C+significant%5C+difference%5C+%5C%28P%5C+%3C%5C+0.05%5C%29%5C+between%5C+wild%5C+%5C%28AR%5C+%3D%5C+5.9%5C%29%5C+and%5C+cultivated%5C+%5C%28AR%5C+%3D%5C+7.1%5C%29%5C+populations%5C+distributed%5C+in%5C+the%5C+same%5C+place%5C+in%5C+Yun%5C+county%2C%5C+Yunnan%5C+province%2C%5C+which%5C+may%5C+result%5C+from%5C+the%5C+hybridization%5C+and%5C+introgression%5C+of%5C+species%5C+in%5C+the%5C+tea%5C+garden%5C+and%5C+anthropogenic%5C+damages%5C+to%5C+the%5C+wild%5C+population.%5C+The%5C+hypothesis%5C+of%5C+hybrid%5C+origin%5C+of%5C+C.%5C+grandibracteata%5C+was%5C+tested%5C+by%5C+morphological%5C+and%5C+microsatellites%5C+analyses.%5C+Compared%5C+with%5C+other%5C+species%2C%5C+the%5C+locules%5C+in%5C+ovary%5C+of%5C+C.%5C+grandibracteata%5C+are%5C+variable%2C%5C+which%5C+showed%5C+a%5C+morphological%5C+intermediate%5C+and%5C+mosaic.%5C+Except%5C+one%5C+private%5C+allele%2C%5C+Ninety%5C-nine%5C+percent%5C+alleles%5C+of%5C+C.%5C+grandibracteata%5C+were%5C+shared%5C+with%5C+these%5C+of%5C+C.%5C+taliensis%5C+and%5C+C.%5C+sinensis%5C+var.%5C+assamica.%5C+And%5C+C.%5C+grandibracteata%5C+was%5C+nested%5C+in%5C+the%5C+cluster%5C+of%5C+C.%5C+taliensis%5C+in%5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Agriculture Research System[CARS-02]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3AChina%5C+Agriculture%5C+Research%5C+System%5C%5BCARS%5C-02%5C%5D"},{"jsname":"Cold stress is one of the major environmental factors that adversely influence plants growth. Cold stress not only limits plants geographic distribution, but also reduces plants yield by shortening growing season, which brought billions of dollars economic losses for global crop. In nature, responses of overwintering plants to low temperature can be divided into three distinct phases: cold acclimation (CA), freezing, and post-freezing recovery (PFR). Until now, plenty intensive study about molecular mechanism of cold stress mainly focused on the above-zero low temperature phase. However, the studies on the freezing phase below zero and the following PFR phase with temperature going up to above-zero were rare. The previous research form our lab hinted that the responses of plants to freezing and PFR were complex and important. Except for passive reflection, there were also crucial active responses during this process. Several special rules were presented at the different levels including gene expression, signal transduction and membrane lipids changes, and fully understanding these rules would be helpful for us to explore the responses of plants to low temperature and then proceed to improve the freezing resistance of plants. In the present study, the mechanisms of respond to freezing and PFR of model plant Arabidopsis thaliana and its close relative Thellungiella halophlia that with extreme tolerance to abiotic stresses were carried out, including regulation of gene expression, signal transduction pathway and membrane lipids changes three levels which were essential for the freezing resistance of plants. Ground on these work, we obtained results from the following five aspects. First, the complete picture of A. thaliana responding to freezing and PFR at transcriptome level was elaborated and three functional genes closely related to the phases were identified. Second, the cis-elements with high frequent presence in differentially expressed genes were elucidated, and the practical binding of one elements among them was experimental verified during freezing and PFR. Moreover, we predicted the new elements which would respond to freezing and PFR. Third, the regulation of freezing stress by microRNA in A. thaliana was preliminarily investigated and 36 functional genes possibly regulated by miRNA during freezing and PFR were gained. Fourth, the negative effect of phytohormone Auxin on A. thaliana subjected to freezing stress was identified. Fifth, for the freezing-resistant plant T. halophlia, the rules of membrane lipids composition changes under freezing stress were uncovered.","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ACold%5C+stress%5C+is%5C+one%5C+of%5C+the%5C+major%5C+environmental%5C+factors%5C+that%5C+adversely%5C+influence%5C+plants%5C+growth.%5C+Cold%5C+stress%5C+not%5C+only%5C+limits%5C+plants%5C+geographic%5C+distribution%2C%5C+but%5C+also%5C+reduces%5C+plants%5C+yield%5C+by%5C+shortening%5C+growing%5C+season%2C%5C+which%5C+brought%5C+billions%5C+of%5C+dollars%5C+economic%5C+losses%5C+for%5C+global%5C+crop.%5C+In%5C+nature%2C%5C+responses%5C+of%5C+overwintering%5C+plants%5C+to%5C+low%5C+temperature%5C+can%5C+be%5C+divided%5C+into%5C+three%5C+distinct%5C+phases%5C%3A%5C+cold%5C+acclimation%5C+%5C%28CA%5C%29%2C%5C+freezing%2C%5C+and%5C+post%5C-freezing%5C+recovery%5C+%5C%28PFR%5C%29.%5C+Until%5C+now%2C%5C+plenty%5C+intensive%5C+study%5C+about%5C+molecular%5C+mechanism%5C+of%5C+cold%5C+stress%5C+mainly%5C+focused%5C+on%5C+the%5C+above%5C-zero%5C+low%5C+temperature%5C+phase.%5C+However%2C%5C+the%5C+studies%5C+on%5C+the%5C+freezing%5C+phase%5C+below%5C+zero%5C+and%5C+the%5C+following%5C+PFR%5C+phase%5C+with%5C+temperature%5C+going%5C+up%5C+to%5C+above%5C-zero%5C+were%5C+rare.%5C+The%5C+previous%5C+research%5C+form%5C+our%5C+lab%5C+hinted%5C+that%5C+the%5C+responses%5C+of%5C+plants%5C+to%5C+freezing%5C+and%5C+PFR%5C+were%5C+complex%5C+and%5C+important.%5C+Except%5C+for%5C+passive%5C+reflection%2C%5C+there%5C+were%5C+also%5C+crucial%5C+active%5C+responses%5C+during%5C+this%5C+process.%5C+Several%5C+special%5C+rules%5C+were%5C+presented%5C+at%5C+the%5C+different%5C+levels%5C+including%5C+gene%5C+expression%2C%5C+signal%5C+transduction%5C+and%5C+membrane%5C+lipids%5C+changes%2C%5C+and%5C+fully%5C+understanding%5C+these%5C+rules%5C+would%5C+be%5C+helpful%5C+for%5C+us%5C+to%5C+explore%5C+the%5C+responses%5C+of%5C+plants%5C+to%5C+low%5C+temperature%5C+and%5C+then%5C+proceed%5C+to%5C+improve%5C+the%5C+freezing%5C+resistance%5C+of%5C+plants.%5C+In%5C+the%5C+present%5C+study%2C%5C+the%5C+mechanisms%5C+of%5C+respond%5C+to%5C+freezing%5C+and%5C+PFR%5C+of%5C+model%5C+plant%5C+Arabidopsis%5C+thaliana%5C+and%5C+its%5C+close%5C+relative%5C+Thellungiella%5C+halophlia%5C+that%5C+with%5C+extreme%5C+tolerance%5C+to%5C+abiotic%5C+stresses%5C+were%5C+carried%5C+out%2C%5C+including%5C+regulation%5C+of%5C+gene%5C+expression%2C%5C+signal%5C+transduction%5C+pathway%5C+and%5C+membrane%5C+lipids%5C+changes%5C+three%5C+levels%5C+which%5C+were%5C+essential%5C+for%5C+the%5C+freezing%5C+resistance%5C+of%5C+plants.%5C+Ground%5C+on%5C+these%5C+work%2C%5C+we%5C+obtained%5C+results%5C+from%5C+the%5C+following%5C+five%5C+aspects.%5C+First%2C%5C+the%5C+complete%5C+picture%5C+of%5C+A.%5C+thaliana%5C+responding%5C+to%5C+freezing%5C+and%5C+PFR%5C+at%5C+transcriptome%5C+level%5C+was%5C+elaborated%5C+and%5C+three%5C+functional%5C+genes%5C+closely%5C+related%5C+to%5C+the%5C+phases%5C+were%5C+identified.%5C+Second%2C%5C+the%5C+cis%5C-elements%5C+with%5C+high%5C+frequent%5C+presence%5C+in%5C+differentially%5C+expressed%5C+genes%5C+were%5C+elucidated%2C%5C+and%5C+the%5C+practical%5C+binding%5C+of%5C+one%5C+elements%5C+among%5C+them%5C+was%5C+experimental%5C+verified%5C+during%5C+freezing%5C+and%5C+PFR.%5C+Moreover%2C%5C+we%5C+predicted%5C+the%5C+new%5C+elements%5C+which%5C+would%5C+respond%5C+to%5C+freezing%5C+and%5C+PFR.%5C+Third%2C%5C+the%5C+regulation%5C+of%5C+freezing%5C+stress%5C+by%5C+microRNA%5C+in%5C+A.%5C+thaliana%5C+was%5C+preliminarily%5C+investigated%5C+and%5C+36%5C+functional%5C+genes%5C+possibly%5C+regulated%5C+by%5C+miRNA%5C+during%5C+freezing%5C+and%5C+PFR%5C+were%5C+gained.%5C+Fourth%2C%5C+the%5C+negative%5C+effect%5C+of%5C+phytohormone%5C+Auxin%5C+on%5C+A.%5C+thaliana%5C+subjected%5C+to%5C+freezing%5C+stress%5C+was%5C+identified.%5C+Fifth%2C%5C+for%5C+the%5C+freezing%5C-resistant%5C+plant%5C+T.%5C+halophlia%2C%5C+the%5C+rules%5C+of%5C+membrane%5C+lipids%5C+composition%5C+changes%5C+under%5C+freezing%5C+stress%5C+were%5C+uncovered."},{"jsname":"Dendrobium officinale is a valuable medicinal plants,mainly distributed in Yunnan, Guangxi and Anhui. It is necessary to understand the environmental adaptation for the effective acclimation and cultivation of this species. Up till now, there is little information on the ecophysiological adaptation of D. officinale, especially on the photosynthetic response to temperature. This paper investigated the response of photosynthesis and growth of D. officinale to temperature, and the stem polysaccharide content of D. officinale at different temperatures, in order to understand how growth temperature affect the growth and development of D. officinale and to determine the suitable temperature ranges and day-night temperature differences for the growth and development of D. officinale. The result are summarized as follows: 1. Temperature has a significant effect on the photosynthetic rate (Pn) of D. officinale, The light saturated photosynthesis at ambient CO2 concentration (Pmax) of the plants were highest at T-30/20. High photosynthetic rate at T-30/20 were related to a larger leaf area (LA) and the more balance between the maximum rate of electron transport and maximum rate of RuBP-mediated carboxylation. 2. Temperature also has a significant effect on the growth and polysaccharide content of D. officinale’s stem. The polysaccharide content of D. officinale at T-20/10 was significantly higher than at the other temperatures, but the stem length, stem node number, stem fresh weight and stem dry weight was the highest at T-30/20. 3. The utilization of solar energy were highest at T-30/15 temperature difference between day and night, it also has the highest content of chlorophyll, and respiration rate was lower, resulting in higher dry matter accumulation and accumulation of relatively higher polysaccharide content. 4. The polysaccharide content of D. officinale T-30/20 temperature difference between day and night was significantly higher than at the other temperatures, but the leaf area was smaller and chlorophyll content, stem length, node number, the average stem length, stem fresh weight and stem dry weight and other indicators are relatively low. 5. My thesis illuminated how temperature affect the growth and development of D. officinale. The suitable temperature ranges and day-night temperature differences for the growth of D. officinale are recommended as below: day temperature is 25℃ ~ 30 ℃, night temperature is 15℃ ~ 20℃, and day-night temperature difference should be maintained at 10℃ ~ 15℃.","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ADendrobium%5C+officinale%5C+is%5C+a%5C+valuable%5C+medicinal%5C+plants%EF%BC%8Cmainly%5C+distributed%5C+in%5C+Yunnan%2C%5C+Guangxi%5C+and%5C+Anhui.%5C+It%5C+is%5C+necessary%5C+to%5C+understand%5C+the%5C+environmental%5C+adaptation%5C+for%5C+the%5C+effective%5C+acclimation%5C+and%5C+cultivation%5C+of%5C+this%5C+species.%5C+Up%5C+till%5C+now%2C%5C+there%5C+is%5C+little%5C+information%5C+on%5C+the%5C+ecophysiological%5C+adaptation%5C+of%5C+D.%5C+officinale%2C%5C+especially%5C+on%5C+the%5C+photosynthetic%5C+response%5C+to%5C+temperature.%5C+This%5C+paper%5C+investigated%5C+the%5C+response%5C+of%5C+photosynthesis%5C+and%5C+growth%5C+of%5C+D.%5C+officinale%5C+to%5C+temperature%2C%5C+and%5C+the%5C+stem%5C+polysaccharide%5C+content%5C+of%5C+D.%5C+officinale%5C+at%5C+different%5C+temperatures%2C%5C+in%5C+order%5C+to%5C+understand%5C+how%5C+growth%5C+temperature%5C+affect%5C+the%5C+growth%5C+and%5C+development%5C+of%5C+D.%5C+officinale%5C+and%5C+to%5C+determine%5C+the%5C+suitable%5C+temperature%5C+ranges%5C+and%5C+day%5C-night%5C+temperature%5C+differences%5C+for%5C+the%5C+growth%5C+and%5C+development%5C+of%5C+D.%5C+officinale.%5C+The%5C+result%5C+are%5C+summarized%5C+as%5C+follows%5C%3A%5C+1.%5C+Temperature%5C+has%5C+a%5C+significant%5C+effect%5C+on%5C+the%5C+photosynthetic%5C+rate%5C+%5C%28Pn%5C%29%5C+of%5C+D.%5C+officinale%2C%5C+The%5C+light%5C+saturated%5C+photosynthesis%5C+at%5C+ambient%5C+CO2%5C+concentration%5C+%5C%28Pmax%5C%29%5C+of%5C+the%5C+plants%5C+were%5C+highest%5C+at%5C+T%5C-30%5C%2F20.%5C+High%5C+photosynthetic%5C+rate%5C+at%5C+T%5C-30%5C%2F20%5C+were%5C+related%5C+to%5C+a%5C+larger%5C+leaf%5C+area%5C+%5C%28LA%5C%29%5C+and%5C+the%5C+more%5C+balance%5C+between%5C+the%5C+maximum%5C+rate%5C+of%5C+electron%5C+transport%5C+and%C2%A0maximum%5C+rate%5C+of%5C+RuBP%5C-mediated%5C+carboxylation.%5C+2.%5C+Temperature%5C+also%5C+has%5C+a%5C+significant%5C+effect%5C+on%5C+the%5C+growth%5C+and%5C+polysaccharide%5C+content%5C+of%5C+D.%5C+officinale%E2%80%99s%5C+stem.%5C+The%5C+polysaccharide%5C+content%5C+of%5C+D.%5C+officinale%5C+at%5C+T%5C-20%5C%2F10%5C+was%5C+significantly%5C+higher%5C+than%5C+at%5C+the%5C+other%5C+temperatures%2C%5C+but%5C+the%5C+stem%5C+length%2C%5C+stem%5C+node%5C+number%2C%5C+stem%5C+fresh%5C+weight%5C+and%5C+stem%5C+dry%5C+weight%5C+was%5C+the%5C+highest%5C+at%5C+T%5C-30%5C%2F20.%5C+3.%5C+The%5C+utilization%5C+of%5C+solar%5C+energy%5C+were%5C+highest%5C+at%5C+T%5C-30%5C%2F15%5C+temperature%5C+difference%5C+between%5C+day%5C+and%5C+night%2C%5C+it%5C+also%5C+has%5C+the%5C+highest%5C+content%5C+of%5C+chlorophyll%2C%5C+and%5C+respiration%5C+rate%5C+was%5C+lower%2C%5C+resulting%5C+in%5C+higher%5C+dry%5C+matter%5C+accumulation%5C+and%5C+accumulation%5C+of%5C+relatively%5C+higher%5C+polysaccharide%5C+content.%5C+4.%5C+The%5C+polysaccharide%5C+content%5C+of%5C+D.%5C+officinale%5C+T%5C-30%5C%2F20%5C+temperature%5C+difference%5C+between%5C+day%5C+and%5C+night%5C+was%5C+significantly%5C+higher%5C+than%5C+at%5C+the%5C+other%5C+temperatures%2C%5C+but%5C+the%5C+leaf%5C+area%5C+was%5C+smaller%5C+and%5C+chlorophyll%5C+content%2C%5C+stem%5C+length%2C%5C+node%5C+number%2C%5C+the%5C+average%5C+stem%5C+length%2C%5C+stem%5C+fresh%5C+weight%5C+and%5C+stem%5C+dry%5C+weight%5C+and%5C+other%5C+indicators%5C+are%5C+relatively%5C+low.%5C+5.%5C+My%5C+thesis%5C+illuminated%5C+how%5C+temperature%5C+affect%5C+the%5C+growth%5C+and%5C+development%5C+of%5C+D.%5C+officinale.%5C+The%5C+suitable%5C+temperature%5C+ranges%5C+and%5C+day%5C-night%5C+temperature%5C+differences%5C+for%5C+the%5C+growth%5C+of%5C+D.%5C+officinale%5C+are%5C+recommended%5C+as%5C+below%5C%3A%5C+day%5C+temperature%5C+is%5C+25%E2%84%83%5C+%5C%7E%5C+30%5C+%E2%84%83%2C%5C+night%5C+temperature%5C+is%5C+15%E2%84%83%5C+%5C%7E%5C+20%E2%84%83%2C%5C+and%5C+day%5C-night%5C+temperature%5C+difference%5C+should%5C+be%5C+maintained%5C+at%5C+10%E2%84%83%5C+%5C%7E%5C+15%E2%84%83."},{"jsname":"In Chapter 1, we isolated a flavonoid prenyltransferase-like gene from traditional Chinese medicinal herb, Epimedium L. (berberidaceae). Epimedium species have a high content of the prenylated flavonol glycosides. Icariin and epimedin A, B and C are frequently used as marker compounds for the quality control of Epimedium. Here we speculate prenyl flavonoids biosynthesis pathway in Epimedium: The flavonoid prenyltransferase is responsible for the prenylation of flavonoids (naringenin 、kaempferol or apigenin) at the 8-position or 3'' or 5''-position. Leaves of Epimedium acuminatum Franch in the nursery were collected every month, and then detected the icariin content. The results show that leaves in March have the highest icariin content. Total RNA was extracted from leaves in March as template. A similarity-based cloning strategy yielded a flavonoid prenyltransferase-like gene, named EaPT1. In E. coli. expression system, pET32a(+) was chosen as the expression vector for use in Rosetta-gamiB(DE3)、RosettaTM 2(DE3)plysS、BL21(DE3)plysE、BL21(DE3)gold and BL21(DE3) cells. The full length ORF and truncated sequence were ligated with pET32a(+). We did not detect the target protein in SDS-PAGE. In Saccharomyces cerevisiae expression system, the full length ORF was ligated with pYES2. In this expression system, we still could not detect the protein in SDS-PAGE. LC/MS did not detect the activity of prenyltransferase, with naringenin as substrate. Chapter 2 describes functional expression and characterization of two copalyl pyrophosphate synthase gene from Isodon ericalyx (Dunn) Kudo, named IeCPS7 and IeCPS11. Their full length ORF and truncated sequence were ligated into pET32a(+). These vectors were used to transform E.coli BL21(DE)3. The truncated IeCPS7 sequence expressed a soluble His-tag recombinant protein, 104699.41D, pI5.87, 924aa. The recombinant protein was characterized for diterpene synthase activity by using geranylgeranyl diphosphate(GGPP) as substrates and subsequent GC/MS analysis of products. The purified recombinant IeCPS showed optimum activity at pH7.1. In addition, IeCPS showed maximum activity at 30℃. The enzymatic activity was increased by addition of MgCl2 to the reaction mixture. Unexpectedly, MnCl2 actually inhibited the enzyme activity. In addition,only insoluble recombinant proteins were expressed for IeCPS11 in BL21(DE)3, Rosetta-gamiB(DE3) and RosettaTM 2(DE3)plysS. The last part reviews the advances in molecular studies of aromatic prenyltransferase in plants and fungi, focusing on membrane-bound homogentisate prenyltransferses, flavonoid prenyltransferases as well as soluble indole prenyltransferases.","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3AIn%5C+Chapter%5C+1%2C%5C+we%5C+isolated%5C+a%5C+flavonoid%5C+prenyltransferase%5C-like%5C+gene%5C+from%5C+traditional%5C+Chinese%5C+medicinal%5C+herb%2C%5C+Epimedium%5C+L.%5C+%5C%28berberidaceae%5C%29.%5C+Epimedium%5C+species%5C+have%5C+a%5C+high%5C+content%5C+of%5C+the%5C+prenylated%5C+flavonol%5C+glycosides.%5C+Icariin%5C+and%5C+epimedin%5C+A%2C%5C+B%5C+and%5C+C%5C+are%5C+frequently%5C+used%5C+as%5C+marker%5C+compounds%5C+for%5C+the%5C+quality%5C+control%5C+of%5C+Epimedium.%5C+Here%5C+we%5C+speculate%5C+prenyl%5C+flavonoids%5C+biosynthesis%5C+pathway%5C+in%5C+Epimedium%5C%3A%5C+The%5C+flavonoid%5C+prenyltransferase%5C+is%5C+responsible%5C+for%5C+the%5C+prenylation%5C+of%5C+flavonoids%5C+%5C%28naringenin%5C+%E3%80%81kaempferol%5C+or%5C+apigenin%5C%29%5C+at%5C+the%5C+8%5C-position%5C+or%5C+3%27%27%5C+or%5C+5%27%27%5C-position.%5C+Leaves%5C+of%5C+Epimedium%5C+acuminatum%5C+Franch%5C+in%5C+the%5C+nursery%5C+were%5C+collected%5C+every%5C+month%2C%5C+and%5C+then%5C+detected%5C+the%5C+icariin%5C+content.%5C+The%5C+results%5C+show%5C+that%5C+leaves%5C+in%5C+March%5C+have%5C+the%5C+highest%5C+icariin%5C+content.%5C+Total%5C+RNA%5C+was%5C+extracted%5C+from%5C+leaves%5C+in%5C+March%5C+as%5C+template.%5C+A%5C+similarity%5C-based%5C+cloning%5C+strategy%5C+yielded%5C+a%5C+flavonoid%5C+prenyltransferase%5C-like%5C+gene%2C%5C+named%5C+EaPT1.%5C+In%5C+E.%5C+coli.%5C+expression%5C+system%2C%5C+pET32a%5C%28%5C%2B%5C%29%5C+was%5C+chosen%5C+as%5C+the%5C+expression%5C+vector%5C+for%5C+use%5C+in%5C+Rosetta%5C-gamiB%5C%28DE3%5C%29%E3%80%81RosettaTM%5C+2%EF%BC%88DE3%EF%BC%89plysS%E3%80%81BL21%5C%28DE3%5C%29plysE%E3%80%81BL21%5C%28DE3%5C%29gold%5C+and%5C+BL21%5C%28DE3%5C%29%5C+cells.%5C+The%5C+full%5C+length%5C+ORF%5C+and%5C+truncated%5C+sequence%5C+were%5C+ligated%5C+with%5C+pET32a%5C%28%5C%2B%5C%29.%5C+We%5C+did%5C+not%5C+detect%5C+the%5C+target%5C+protein%5C+in%5C+SDS%5C-PAGE.%5C+In%5C+Saccharomyces%5C+cerevisiae%5C+expression%5C+system%2C%5C+the%5C+full%5C+length%5C+ORF%5C+was%5C+ligated%5C+with%5C+pYES2.%5C+In%5C+this%5C+expression%5C+system%2C%5C+we%5C+still%5C+could%5C+not%5C+detect%5C+the%5C+protein%5C+in%5C+SDS%5C-PAGE.%5C+LC%5C%2FMS%5C+did%5C+not%5C+detect%5C+the%5C+activity%5C+of%5C+prenyltransferase%2C%5C+with%5C+naringenin%5C+as%5C+substrate.%5C+Chapter%5C+2%5C+describes%5C+functional%5C+expression%5C+and%5C+characterization%5C+of%5C+two%5C+copalyl%5C+pyrophosphate%5C+synthase%5C+gene%5C+from%5C+Isodon%5C+ericalyx%5C+%5C%28Dunn%5C%29%5C+Kudo%2C%5C+named%5C+IeCPS7%5C+and%5C+IeCPS11.%5C+Their%5C+full%5C+length%5C+ORF%5C+and%5C+truncated%5C+sequence%5C+were%5C+ligated%5C+into%5C+pET32a%5C%28%5C%2B%5C%29.%5C+These%5C+vectors%5C+were%5C+used%5C+to%5C+transform%5C+E.coli%5C+BL21%5C%28DE%5C%293.%5C+The%5C+truncated%5C+IeCPS7%5C+sequence%5C+expressed%5C+a%5C+soluble%5C+His%5C-tag%5C+recombinant%5C+protein%2C%5C+104699.41D%2C%5C+pI5.87%2C%5C+924aa.%5C+The%5C+recombinant%5C+protein%5C+was%5C+characterized%5C+for%5C+diterpene%5C+synthase%5C+activity%5C+by%5C+using%5C+geranylgeranyl%5C+diphosphate%5C%28GGPP%5C%29%5C+as%5C+substrates%5C+and%5C+subsequent%5C+GC%5C%2FMS%5C+analysis%5C+of%5C+products.%5C+The%5C+purified%5C+recombinant%5C+IeCPS%5C+showed%5C+optimum%5C+activity%5C+at%5C+pH7.1.%5C+In%5C+addition%2C%5C+IeCPS%5C+showed%5C+maximum%5C+activity%5C+at%5C+30%E2%84%83.%5C+The%5C+enzymatic%5C+activity%5C+was%5C+increased%5C+by%5C+addition%5C+of%5C+MgCl2%5C+to%5C+the%5C+reaction%5C+mixture.%5C+Unexpectedly%2C%5C+MnCl2%5C+actually%5C+inhibited%5C+the%5C+enzyme%5C+activity.%5C+In%5C+addition%2Conly%5C+insoluble%5C+recombinant%5C+proteins%5C+were%5C+expressed%5C+for%5C+IeCPS11%5C+in%5C+BL21%5C%28DE%5C%293%2C%5C+Rosetta%5C-gamiB%5C%28DE3%5C%29%5C+and%5C+RosettaTM%5C+2%EF%BC%88DE3%EF%BC%89plysS.%5C+The%5C+last%5C+part%5C+reviews%5C+the%5C+advances%5C+in%5C+molecular%5C+studies%5C+of%5C+aromatic%5C+prenyltransferase%5C+in%5C+plants%5C+and%5C+fungi%2C%5C+focusing%5C+on%5C+membrane%5C-bound%5C+homogentisate%5C+prenyltransferses%2C%5C+flavonoid%5C+prenyltransferases%5C+as%5C+well%5C+as%5C+soluble%5C+indole%5C+prenyltransferases."},{"jsname":"Major State Basic Research Development Program[2010CB951704]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3AMajor%5C+State%5C+Basic%5C+Research%5C+Development%5C+Program%5C%5B2010CB951704%5C%5D"},{"jsname":"National Key Laboratory of Crop Genetic Improvement","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Key%5C+Laboratory%5C+of%5C+Crop%5C+Genetic%5C+Improvement"},{"jsname":"National Key Research and Development Program of China[2017YFD0201802]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Key%5C+Research%5C+and%5C+Development%5C+Program%5C+of%5C+China%5C%5B2017YFD0201802%5C%5D"},{"jsname":"National Natural Science Foundation of China (NSFC)[41271058]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C+%5C%28NSFC%5C%29%5C%5B41271058%5C%5D"},{"jsname":"National Natural Science Foundation of China[31570311]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C%5B31570311%5C%5D"},{"jsname":"National Natural Science Foundation of China[31571262]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C%5B31571262%5C%5D"},{"jsname":"National Natural Science Foundation of China[31670342]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C%5B31670342%5C%5D"},{"jsname":"National Natural Science Foundation of China[41671280]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C%5B41671280%5C%5D"},{"jsname":"National Natural Science Foundation of China[41701317]","jscount":"1","jsurl":"/simple-search?field1=all&field=eperson.unique.id&advanced=false&query1=Maize%2B%2528Zea%2BMays%2BL.%2529&&fq=dc.project.title_filter%3ANational%5C+Natural%5C+Science%5C+Foundation%5C+of%5C+China%5C%5B41701317%5C%5D"},{"jsname":"lastIndexed","jscount":"2024-04-15"}],"资助项目","dc.project.title_filter")'>
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共51条,第1-20条
杨永平
23
吴建强
14
杨云强
13
李德铢
11
许建初
9
李雄
9
刘爱忠
8
王蕾
8
李京
8
高立志
7
徐伟
7
庄会富
6
郭振华
6
刘莉
6
章成君
4
yang jing
4
杨祝良
3
张雪梅
3
孙桂玲
3
普晓俊
3