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Showing 1 to 10 of 65 (0.058 seconds)Spelling suggestions: "subject:"sesquiterpene"" "subject:"sesquiterpenes""
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Cloning and characterisation of (#EPSILON#) β farnesene synthase genesAdams, Racheal January 2002 (has links)
No description available.
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| 2 |
Approaches to the synthesis of euparotinHasenhuettl, Gerard Leo 05 1900 (has links)
No description available.
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| 3 |
Studies in the synthesis of cyclopentanoid sesquiterpene natural productsTelfer, S. January 1984 (has links)
No description available.
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| 4 |
Studies on Bioactive Sesquiterpene Lactones From Eupatorium hualienense, Ou, Chung & PengJang, Jiun-yang 28 July 2004 (has links)
Sesquiterpene lactones contain £\,£]-unsaturated-£^-lactone as a major structural feature, which in recent studies have been shown to be associ-
ated with anti-tumor, cytotoxic, anti-microbial and phytotoxic activities. Previous researchers isolated sesquiterpene lactones from Eupatorium formosanum Hay. Thus, we studied Eupatorium hualienense, a unique speces in Taiwan that grows near the eastern coast. Five new sesquiter-
pene lactones of the germacranolide type, eupahualins A-E (1-5) along with the known lactone, eupasimplicin B (6). Their structures were determined by 1D-NMR(1H-NMR,13C-NMR) and 2D-NMR(COSY¡BNOESY¡BHMQC¡BHMBC).
Eupahualin A (1) exhibits an aldehyde at C-10 and an a,b-unsatura
ted acyl group at C-8. Eupahualin B (2) also has an aldehyde at C-10. The Z-form of C-4, C-5 double bond in eupahualin B (2) is the main difference from the trans-form C-4, C-5 double bond in eupahualin A (1). The difference of eupahualin C (3) and eupahualin A (1) lies in structure of a ester group at C-8. The methyl at C-4' in eupahualin A (1) was changed into hydroxy methyl while the hydroxy methyl of eupahualin A (1) was changed to methyl in eupahualin C (3). Eupahualin D (4) shows exocyclic double bond at C-10, OH at C-1 and OAc at C-3. An carboxylic group (COOH) at C-10 in eupahualin E (5) is the only difference from which in eupahualin A (1).
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| 5 |
The total synthesis of (±)-3-0X0--cadinol and (±)--cadinol, Part I. Part II, Direct synthesis of -lactones by reaction of lithium [subscript]-lithio carboxylates with carbonyl compoundsFrobese, Alfred Stephen 12 1900 (has links)
No description available.
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| 6 |
Total synthesis of polyquinane sesquiterpenes /Schostarez, Heinrich Josef January 1982 (has links)
No description available.
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| 7 |
Molekulare und genetische Aspekte der Biosynthese von komplexen Sesquiterpengemischen in MaisKöllner, Tobias G. Unknown Date (has links) (PDF)
Universiẗat, Diss., 2004--Jena.
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| 8 |
Molekulare und genetische Aspekte der Biosynthese von komplexen Sesquiterpengemischen in MaisKöllner, Tobias G. January 2004 (has links) (PDF)
Jena, Univ., Diss., 2004
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| 9 |
The structures of a number of sesquiterpene lactones, and an empirical treatment of X-ray absorption /Beno, Mark Anthony January 1979 (has links)
No description available.
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| 10 |
The Evolutionary Ecology of Stereoisomeric Sesquiterpene Lactones in Xanthium strumariumAhern, Jeffrey 13 May 2013 (has links)
The ecological factors that maintain defensive chemical variation within and between plant species have intrigued ecologists for decades. While theory posits that polymorphisms may be maintained different forms of balancing selection, relatively few experimental studies have tested whether such balancing selection can maintain defensive chemical trait polymorphisms in nature. Further, evidence demonstrating balancing selection is rare for any trait. Here, I investigated a stereochemical trait polymorphism in Xanthium strumarium. This species is polymorphic with respect to the stereochemistry of the lactone ring junction of a prominent defensive compound class ? the sesquiterpene lactones. Individual plants typically produce only cis-fused or trans-fused lactones across their entire suite of compounds. Sesquiterpene lactones are known to influence feeding behavior and growth rates of various herbivores, but nothing is known about the ecological implications of variation in this stereochemical trait. I first examined whether sesquiterpene lactone stereochemical variation can influence folivore feeding behavior in the laboratory. Using pure sesquiterpene lactones in controlled feeding experiments, I found that laboratory-reared grasshoppers were less deterred by the cis-fused compounds than the trans-fused compounds. I then found that these patterns extended to the field: in common gardens, plants producing cis-fused lactones received more damage than plants producing trans-fused lactones. Additionally, folivore damage was negatively correlated with plant fitness. Taken together, these results indicate that herbivores can impose natural selection on this stereochemical trait polymorphism in nature. Finally, I found evidence that spatially variable selection leads to fitness patterns conducive to the maintenance of this polymorphism. Further, I found that the intensity of folivore damage across spatial scales predicted in which environments each morph outperformed the other, with plants producing cis-fused lactones achieving higher fitness than plants producing trans-fused lactones when herbivore pressure was low (and the reverse being true when herbivore pressure was high). This work demonstrates that relatively minor defensive chemical variation can have far-reaching impacts on the ecology and evolution of plant populations.
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