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Ginkgolides are biologically active terpenic
While researchers have published chemical pathways to make this molecule, most of the designed syntheses were too complex and produced little of the actual material to run full analyses. Therefore, studying the biosynthesis of the molecule is preferable.
Most of the natural product terpenoids start with isopentenyl diphosphate synthesized by the MEP pathway. This pathway also generates dimethylallyl diphosphate, from pyruvate and D-glyercaldehyde 3-phosphate (GAP). When coupled together, they form one molecule of geranylgeranyl diphosphate with geranylgeranyl diphosphate synthase.
A molecule of GGPP generates (1) (+)-copalyl in the presence of levopimaradiene synthase. (a) Then (1) loses its OPP group catalyzed by this same synthase, performing an intramolecular allylic cyclization with the two alkenes, to form (2) the sandaracopimarenyl cation. (b) This cation then undergoes an internal cyclization to stabilize the carbocation in the ring by proton transfer to form (3) intermediate.
(c) By doing this, the molecule sets itself up for a methyl migration to stabilize that secondary cation and generate that tertiary carbocation at (4). (d) This induces a loss of proton to get (5) levopimaradiene. (e) With oxidation, a loss of a proton to form an aromatic ring generates (6) abietatriene. (g) This newly formed abietatriene undergoes a 1,2-alkyl shift to break the 6-membered ring into (7) with a five-membered ring (more favorable). (h) Another 1,2-alkyl shift takes place at the same time a ring cleavage takes place to generate (8). (i) Oxidation at all the positions with alkenes generates (9) intermediate which then undergoes ring closures featuring one hemiacetal and all three lactones to get ginkgolide B at (10).
Ginkgolides are biologically active terpenic lactone
Lactones are cyclic carboxylic esters, containing a 1-oxacycloalkan-2-one structure (), or analogues having unsaturation or heteroatoms replacing one or more carbon atoms of the ring.
Lactones are formed by intramolecular esterification of the co ...
s present in ''Ginkgo biloba
''Ginkgo biloba'', commonly known as ginkgo or gingko ( ), also known as the maidenhair tree, is a species of tree native to China. It is the last living species in the order Ginkgoales, which first appeared over 290 million years ago. Fossil ...
''. They are diterpenoid
Diterpenes are a class of chemical compounds composed of four isoprene units, often with the molecular formula C20H32. They are biosynthesized by plants, animals and fungi via the HMG-CoA reductase pathway, with geranylgeranyl pyrophosphate being ...
s with 20-carbon skeletons, which are biosynthesized from geranylgeranyl pyrophosphate
Geranylgeranyl pyrophosphate is an intermediate in the biosynthesis of diterpenes and di terpenoids. It is also the precursor to carotenoids, gibberellins, tocopherols, and chlorophylls.
It is also a precursor to geranylgeranylated proteins, wh ...
.
Examples
Ginkgolide B
Ginkgolide B, specifically, is a diterpenoid trilactone with six five-membered rings. It contains a spiro ,4nonane carbocyclic ring, a tetrahydrofuran ring, and a very specific tert-butyl group at one of the rings (Figure 1). The class of ginkgolides was first isolated from the tree ''Ginkgo biloba
''Ginkgo biloba'', commonly known as ginkgo or gingko ( ), also known as the maidenhair tree, is a species of tree native to China. It is the last living species in the order Ginkgoales, which first appeared over 290 million years ago. Fossil ...
'' in 1932. Structural elucidation was accomplished in 1967 by Maruyama ''et al''.
Background
It is extracted from the root bark and leaves of the ''Ginkgo biloba
''Ginkgo biloba'', commonly known as ginkgo or gingko ( ), also known as the maidenhair tree, is a species of tree native to China. It is the last living species in the order Ginkgoales, which first appeared over 290 million years ago. Fossil ...
'' (' meaning "silver apricot") tree found native in China. It is marketed to other countries that include Korea, France, the United States, etc. for the drug and clinical properties of the extracts. Present in the tree is less than 0.1 to 0.25% of ginkgolide B, the most abundant being ginkgolide A.
Potential applications
This class of molecules has been studied for its potential to act as a platelet-activating factor receptor antagonist. Ginkgolide B has been investigated for its potential to reducing migraine frequency. Ginkgolide B is also used in treatment for cerebrovascular disease. Research has also proven that ginkgolide B can also treat migraines in young ages. The literature indicates that ginkgolide B functions as a selective antagonist ofglycine receptors
The glycine receptor (abbreviated as GlyR or GLR) is the receptor of the amino acid neurotransmitter glycine. GlyR is an ionotropic receptor that produces its effects through chloride current. It is one of the most widely distributed inhibitory ...
based on noncompetitive inhibition for the neurological system that this compound performs.
Spectroscopic studies for the elucidation of the individual structures for the ginkgolides
Ginkolides A - C were isolated from a large scale methanolic extraction followed by liquid-liquid partitions, column chromatography and repeated crystallizations. The molecular formulas were determined by high resolution mass spectrometry, and the overall structures by IR and NMR spectroscopic analysis and extensive derivitization techniques.Biosynthesis of ginkgolide B
While researchers have published chemical pathways to make this molecule, most of the designed syntheses were too complex and produced little of the actual material to run full analyses. Therefore, studying the biosynthesis of the molecule is preferable.
Most of the natural product terpenoids start with isopentenyl diphosphate synthesized by the MEP pathway. This pathway also generates dimethylallyl diphosphate, from pyruvate and D-glyercaldehyde 3-phosphate (GAP). When coupled together, they form one molecule of geranylgeranyl diphosphate with geranylgeranyl diphosphate synthase.
A molecule of GGPP generates (1) (+)-copalyl in the presence of levopimaradiene synthase. (a) Then (1) loses its OPP group catalyzed by this same synthase, performing an intramolecular allylic cyclization with the two alkenes, to form (2) the sandaracopimarenyl cation. (b) This cation then undergoes an internal cyclization to stabilize the carbocation in the ring by proton transfer to form (3) intermediate.
(c) By doing this, the molecule sets itself up for a methyl migration to stabilize that secondary cation and generate that tertiary carbocation at (4). (d) This induces a loss of proton to get (5) levopimaradiene. (e) With oxidation, a loss of a proton to form an aromatic ring generates (6) abietatriene. (g) This newly formed abietatriene undergoes a 1,2-alkyl shift to break the 6-membered ring into (7) with a five-membered ring (more favorable). (h) Another 1,2-alkyl shift takes place at the same time a ring cleavage takes place to generate (8). (i) Oxidation at all the positions with alkenes generates (9) intermediate which then undergoes ring closures featuring one hemiacetal and all three lactones to get ginkgolide B at (10).
See also
* BilobalideReferences
{{PAF signaling Gamma-lactones Diterpenes Glycine receptor antagonists Tert-butyl compounds Cyclopentanes