Steroidal alkaloid

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Chemical structure of solanidine, a steroidal alkaloid found in potatoes

Steroidal alkaloids have organic ring backbones which feature nitrogen-based functional groups. More specifically, they are distinguished by their tetracyclic cyclopentanophenanthrene backbone that marks their close relationship with sterols.[1] They fall in two major categories: Solanum alkaloids and Veratrum alkaloids.[1] A Steroidal alkaloid has also been found in Chonemorpha fragrans (Frangipani vine), 'chonemorphine' was used to treat intestinal infections in Wistar rats. (Chatterjee DK et al (1987) Parasitol Res 74, 1, 30-33).[2]

Solanum alkaloids[]

These compounds generally appear as their corresponding glycoside in plants of the genus Solanum.[3] Solanum includes plants like potatoes, tomatoes, and various nightshades[3] Starting with cholesterol, the biosynthesis of these compounds follow a similar general mechanism including hyroxylation, oxidation, and transamination before differentiating.[4] Alkaloids found in these plants include chaconine, solanine, solasodine, tomatidine, tomatine, and solanidine.[1] Typically they are used in plants as a protection mechanism against animals. Due to the typical anti-cholinesterase activity, they can be used as poisons against the plants' predators. They can be used as starting materials for steroidal drugs.[1] There are various tests for identifying these alkaloids. The characteristic test involves dissolving the compound in hot amyl alcohol or ethanol and watching for the formation of a jelly-like product as the mixture cools.[1]

Veratrum alkaloids[]

True to their name, Veratrum alkaloids come from plants of the genus Veratrum. Alkaloids are found in the roots and rhizomes of these plants.[5] They include veratridine, cyclopamine, and jervine.[3] Because of their actions on the cardiovascular, neuromuscular, and respiratory systems, Veratrum alkaloids have been used for the treatment of various conditions like myasthenia gravis, hypotension, and eclampsia.[5]

Bioactivity[]

Steroidal alkaloids have been investigated for a wide range of potential bioactivities including antimicrobial, anti-inflammatory, anti-estrogenic, and chemotherapeutic[6] activity. These bioactivities are the result of a wide array of mechanisms across different compounds. For example, solasodine antimicrobial bioactivity is accomplished by interfering with the synthesis of genetic substances in Saccharomyces cerevisiae and Prototheca wickerhamii. Solasodine inhibits growth signaling in Geim original algal. On the other hand, tomatidine synergistically works with aminoglycosides as antibiotics against S. aureus.[7]

Antiinflammation is similarly accomplished with a variety of mechanisms. Solasodine, for example, reduces interleukin-2 and -8 production whereas tomatidine inhibits specific nuclear translocation, JNK activation, as well as induce nitrous oxide synthase. Lastly, nine steroidal alkaloids have significant antiestrogenic activity whereas seven inhibit estrone sulfatase.[7]

However, in addition to their therapeutic benefits, steroidal alkaloids, specifically veratrum alkaloids, are potentially deadly.

Veratrum alkaloid compounds act by attaching to voltage-gated sodium ion channels, altering their permeability.[8] Veratrum alkaloids cause affected sodium channels to reactivate 1000x slower than unaffected channels.[8] Furthermore, veratrum alkaloids block inactivation of sodium channels and lower their activation threshold so they remain open even at resting potential.[8] As a result, sodium concentrations within the cell rise, leading to increased nerve and muscle excitability.[9] These biochemical channels cause muscle contractions, repetitive firing of the nerves and an irregular heart rhythm caused by stimulation of vagal nerves which control the parasympathetic functions of the heart, lungs and digestive tract.[9]

References[]

  1. ^ a b c d e "Steroidal Alkaloids". Pharmacognosy. July 2012. Retrieved 2018-05-05.
  2. ^ Wiart Christophe Medicinal Plants Of The Asia-pacific: Drugs For The Future (2006), p. 454, at Google Books
  3. ^ a b c "Steroid Alkaloids". Cornell University Department of Animal Science. Retrieved 2018-05-05.
  4. ^ Ohyama K, Okawa A, Moriuchi Y, Fujimoto Y (May 2013). "Biosynthesis of steroidal alkaloids in Solanaceae plants: involvement of an aldehyde intermediate during C-26 amination". Phytochemistry. 89 (17): 26–31. doi:10.1016/j.phytochem.2013.01.010. PMID 23473422.
  5. ^ a b Hollman A (May 1991). "Veratrum alkaloids". British Heart Journal. 65 (5): 286. doi:10.1136/hrt.65.5.286. PMC 1024632. PMID 18610390.
  6. ^ Dey, Prasanta; Kundu, Amit; Chakraborty, Hirak Jyoti; Kar, Babli; Choi, Wahn Soo; Lee, Byung Mu; Bhakta, Tejendra; Atanasov, Atanas G.; Kim, Hyung Sik (2018). "Therapeutic value of steroidal alkaloids in cancer: Current trends and future perspectives". International Journal of Cancer. doi:10.1002/ijc.31965. PMC 6767045. PMID 30387881.
  7. ^ a b Jiang QW, Chen MW, Cheng KJ, Yu PZ, Wei X, Shi Z (January 2016). "Therapeutic Potential of Steroidal Alkaloids in Cancer and Other Diseases". Medicinal Research Reviews. 36 (1): 119–43. doi:10.1002/med.21346. PMID 25820039.
  8. ^ a b c Furbee B (2009). "Neurotoxic plants". Clinical Neurotoxicology: Syndromes, Substances, Environments. Elsevier Inc.
  9. ^ a b Heilpern KL (February 1995). "Zigadenus poisoning". Annals of Emergency Medicine. 25 (2): 259–62. doi:10.1016/S0196-0644(95)70336-5. PMID 7832360.
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