Forskolin (coleonol) is a labdanediterpene produced by the plant Coleus barbatus (blue spur flower). Other names include pashanabhedi, Indian coleus, makandi, HL-362, mao hou qiao rui hua.[2] As with other members of the large diterpene class of plant metabolites, forskolin is derived from geranylgeranyl pyrophosphate (GGPP). Forskolin contains some unique functional elements, including the presence of a tetrahydropyran-derived heterocyclic ring.
Forskolin is commonly used in laboratory research to increase levels of cyclic AMP by stimulation of adenylate cyclase.[2]
Mechanism of action
Forskolin is used in biochemistry experiments to raise levels of cyclic AMP (cAMP) in studies of cell physiology.[2][3] Forskolin activates the enzyme adenylyl cyclase and increases intracellular levels of cAMP. cAMP is an important second messenger necessary for the proper biological response of cells to hormones and other extracellular signals. It is required for cell communication in the hypothalamus-pituitary gland axis, and for the feedback control of hormones via induction of corticotropin-releasing factor gene transcription.[4] Cyclic AMP acts by activating cAMP-sensitive pathways such as protein kinase A and EPAC1.
Chemistry
It is defined as a category 4 chemical with acute dermal toxicity based on 2012 OSHA Hazard Communication Standard (29 CFR 1910.1200).[5]
A total chemical synthesis has been reported. The key step of this chemical synthesis is photocyclization of a synthetic intermediate in presence of oxygen and methylene blue, followed by a singlet oxygen Diels-Alder reaction.[10]
Biosynthesis
The heterocyclic ring is synthesized after the formation of the trans-fused carbon ring systems formed by a carbocation mediated cyclization. The remaining tertiary carbocation is quenched by a molecule of water. After deprotonation, the remaining hydroxy group is free to form the heterocyclic ring. This cyclization can occur either by attack of the alcohol oxygen onto the allylic carbocation formed by loss of diphosphate, or by an analogous SN2'-like displacement of the diphosphate.[11] This forms the core ring system A of forskolin.
The remaining modifications of the core ring system A can putatively be understood as a series of oxidation reactions to form a poly-ol B which is then further oxidized and esterified to form the ketone and acetate ester moieties seen in forskolin. However, because the biosynthetic gene cluster has not been described, this putative synthesis could be incorrect in the sequence of oxidation/esterification events, which could occur in almost any order.
Weight loss
Although forskolin has been used in preliminary weight loss research, the low quality of the studies and inconclusive results prevented any determination of effects.[12]
^ abc"Forskolin". Drugs.com. 20 November 2023. Retrieved 28 November 2024.
^Alasbahi, RH; Melzig, MF (January 2012). "Forskolin and derivatives as tools for studying the role of cAMP". Die Pharmazie. 67 (1): 5–13. doi:10.1691/ph.2012.1642. PMID22393824.
^Morinobu S, Fujimaki K, Okuyama N, Takahashi M, Duman RS (May 1999). "Stimulation of adenylyl cyclase and induction of brain-derived neurotrophic factor and TrkB mRNA by NKH477, a novel and potent forskolin derivative". Journal of Neurochemistry. 72 (5): 2198–205. doi:10.1046/j.1471-4159.1999.0722198.x. PMID10217303.
^Li Z, Wang J (November 2006). "A forskolin derivative, FSK88, induces apoptosis in human gastric cancer BGC823 cells through caspase activation involving regulation of Bcl-2 family gene expression, dissipation of mitochondrial membrane potential and cytochrome c release". Cell Biology International. 30 (11): 940–6. doi:10.1016/j.cellbi.2006.06.015. PMID16889987. S2CID7288869.