Incensole Explained

Incensole is a C20 diterpene alcohol and biomarker for some plants of the Boswellia genus. It, along with its acetate ester incensole acetate, is an abundant component of frankincense, the resin collected from Boswellia trees.[1] Incensole is used archaeologically to assist in identifying trade routes and distinguishing the identity of frankincense from other resins which may have been used together in incense and other salves. Incensole has also been deemed to be an active component in medicinal frankincense.  

History

Incensole was first isolated in 1966 at the University of Rome's Institute of Organic Chemistry by S. Corsano and R. Nicoletti while investigating the neutral components of Boswellia carteri resin.[2] There was some controversy as to whether the sample analyzed by S. Corsano and R. Nicoletti was actually from B. carteri and some believed that the original sample was from a B. papyrifera specimen. Further testing done by H. Obermann in 1977 identified an "Eritrea" type B. carteri sample (so named because it originated from the Eritrea region) which displayed incensole levels consistent with those found by Corsano and Nicoletti, but the sample specimen was likely B. papyrifera misidentified as B. carteri.[3] In 2005, incensole was used as a biomarker for frankincense (also known as olibanum) in order to determine the composition of Ancient Egyptian mummification balms and unguents,[4] speaking to its role in studying the history of religion.

Chemistry

Oily in appearance, incensole has low volatility. It can be synthetically prepared from cembrene,[5] a terpenoid, and cembrenol (serratol), its biologic precursor. Diterpenes and terpenoids are classes of biomarkers which are synthesized in plants and have been found in insects,[6] possibly because of accumulation of terpenoids within their diets.[7] Terpenoids have gained special interest due to their potential as anti-inflammatories, chemotherapies, and antiparasitics.

Biosynthetic pathway

It has been proposed that incensole is produced in Boswellia plants via serratol from geranylgeranyl pyrophosphate (GGPP), a C20 precursor for many metabolic branches such as the chlorophyll, carotenoid, and gibberellin biosynthetic pathways.[8] To begin, GGPP loses its pyrophosphate group enabling it to be 1,14-cyclized to form cembrene after the loss of a proton. Cembrene is then hydrolyzed to form serratol which in turn undergoes epoxidation and intramolecular cyclization to form incensole. Though this has been used to make incensole synthetically, the abundances of incensole, serratol, incensole acetate, and iso-serratol in Boswellia species known to produce incensole are inconsistent with what would be expected if this pathway occurred in situ.

Sources of Incensole

Incensole is mainly found in the resin of Boswellia trees which grow in a region across Northern Africa from Ethiopia to Nigeria.[9] Boswellia trees prefer to grow in arid, stony regions, and cuts to the body of the trees seep frankincense resin which hardens and darkens when exposed to the air. Incensole is a biomarker of frankincense from certain Boswellia species; these species are B. papyrifera, B. occulta, B. carteri, B. sacra,[10] [11] [12] and possibly B. serrata though there are conflicting results as to whether it really produces incensole. B. carteri and B. sacra have been determined to actually be the same species, except that B. carteri is native to Africa while B. sacra is native to South Arabia.

It has also been proposed that incensole and incensole acetate can be derived from other sources such as these:

Gas chromatography and mass spectrometry were used to identify incensole in these specimen, but to conclusively identify these species as producers of incensole/incensole acetate, isolation and structural elucidation from these species would have to occur.

Detection and characterization

Incensole was originally isolated in 1966 by S. Corsano and R. Nicoletti using several ether extractions and vacuum separations, and then characterized using UV-Vis, IR, and H-NMR spectroscopy. They found incensole to have no UV-Vis absorption above 210 mμ. The distinguishing IR and H-NMR peaks of incensole are reported in the tables below, and the observed mass spectrum of incensole from a study done in 2014 on frankincense in incense pots is pictured to the right.[13]

IR Peaks of Incensole!Wave Number (cm−1)!Peak Identity
3620-OH
1670C=C
1375, 1390CH3-C-CH3
1050C-O
NMR Peaks of Incensole in CCl4 at 60 Mc!Chemical Shift (ppm)!Protons[14] !Group Identity
0.90(d, 6H, J = 6.5 c/s)isopropyl
1.02(s, 3H)CH3-C-O
1.48, 1.61(s, 3H)CH3-C=
3.18(d, 1H, J = 10 c/s)HC-OH
5.06(2H, broad signal)CH3CH=C(CH3)2
Incensole is most often extracted by chromatographic extractions and hydrodistillations, which produce a frankincense essential oil. Incensole is typically characterized by GC/MS although thin layer chromatography and near-infrared spectroscopy[15] .

Unfortunately, within some of the earlier literature, frankincense biomarker compositions have been misattributed to different Boswellia species, as was seen in the mistaken attribution of the first extraction of incensole being from a B. carteri specimen when it likely came from a B. papyrifera specimen. This is likely because the taxonomic certifications for frankincense bought from market as opposed to collected straight from the tree are often faulty or absent.

In archaeology

Frankincense has been used for thousands of years in religious ceremonies and for medicinal purposes. In fact, by tracing incensole's degraded products, historians have been able to use it to understand the historical use of incense in religion. In one such case, the examination of incensole as a biomarker led to the identification of certain porous pots buried in medieval, Belgian, Christian graves as incense burners. Further study indicated that though frankincense was a main component of funerary incense at the time, other, cheaper local resins were mixed into the incense, possibly to reduce cost.

Additionally, frankincense has been used for thousands of years as medicine. It is listed in texts such as the Papyrus Ebers and the Syriac book of medicine and was prescribed by the practitioners Celsus and Culpepper as a remedy for a variety of ailments from stomach ulcers and gastrointestinal hemorrhages to gout and open wounds. Modern analysis on the medicinal efficacy of frankincense has revealed incensole and incensole acetate, along with boswellic acids, to be the bioactive ingredients of frankincense.

Due to its religious and medicinal significance, frankincense and its biomarker components, like incensole, can be found all over the world in Europe, Asia, the Mediterranean, and the Middle East[16] as the result of global trade.

Medicinal properties

Previously, the therapeutic properties of frankincense had been attributed to boswellic acids within the resin, but research from 2019 and 2020 has found incensole and its acetate ester to be major contributors to frankincense's therapeutic efficacy. This research has found incensole to act as an anti-inflammatory and neuroprotective compound after murine head-trauma on top of exhibiting anxiolytic, anti-depressive, and sedative effects in mice.

It is proposed that incensole works as an anti-inflammatory through the inhibition of the NF-κB pathway which is responsible for the increased production of proinflammatory proteins. Insensitivity in the NF-κB pathway is correlated to arthritis, asthma, inflammatory bowel disease, ataxia telangiectasia, cancers, and neurodegenerative diseases.[17]

It has also been found that incensole acetate activates the TRPV3 channel which is responsible for regulating wound healing and the perception of pain and itching, among other things.[18] It is thought that this is another key component of incensole's role as an anti-inflammatory agent.

Incensole has also been cited as a potential antibacterial against Bacillus.

Notes and References

  1. Moussaieff A, Mechoulam R . Boswellia resin: from religious ceremonies to medical uses; a review of in-vitro, in-vivo and clinical trials . The Journal of Pharmacy and Pharmacology . 61 . 10 . 1281–1293 . October 2009 . 19814859 . 10.1211/jpp.61.10.0003 . 98846742 . free .
  2. Corsano S, Nicoletti R . January 1967 . The structure of incensole . Tetrahedron . en . 23 . 4 . 1977–1984 . 10.1016/S0040-4020(01)82601-6 . 0040-4020.
  3. Al-Harrasi A, Csuk R, Khan A, Hussain J . May 2019 . Distribution of the anti-inflammatory and anti-depressant compounds: Incensole and incensole acetate in genus Boswellia . Phytochemistry . 161 . 28–40 . 2019PChem.161...28A . 10.1016/j.phytochem.2019.01.007 . 30802641 . 73501446.
  4. Hamm S, Bleton J, Connan J, Tchapla A . A chemical investigation by headspace SPME and GC-MS of volatile and semi-volatile terpenes in various olibanum samples . Phytochemistry . 66 . 12 . 1499–1514 . June 2005 . 15922374 . 10.1016/j.phytochem.2005.04.025 . 2005PChem..66.1499H .
  5. Strappaghetti G, Proietti G, Corsano S, Grgurina I . March 1982 . Synthesis of incensole . Bioorganic Chemistry . en . 11 . 1 . 1–3 . 10.1016/0045-2068(82)90042-6.
  6. Majhi S . 2020-10-29 . Diterpenoids: Natural Distribution, Semisynthesis at Room Temperature and Pharmacological Aspects‐A Decade Update . ChemistrySelect . en . 5 . 40 . 12450–12464 . 10.1002/slct.202002836 . 225109058 . 2365-6549.
  7. Book: Peters KE, Walters CC, Moldowan JM . The Biomarker Guide . Cambridge University Press . 978-1-107-32604-0 . 1030120220.
  8. Zhou F, Wang CY, Gutensohn M, Jiang L, Zhang P, Zhang D, Dudareva N, Lu S . 6 . A recruiting protein of geranylgeranyl diphosphate synthase controls metabolic flux toward chlorophyll biosynthesis in rice . Proceedings of the National Academy of Sciences of the United States of America . 114 . 26 . 6866–6871 . June 2017 . 28607067 . 5495272 . 10.1073/pnas.1705689114 . 2017PNAS..114.6866Z . free .
  9. Web site: Boswellia papyrifera (Delile) Hochst. . African Plant Database . 2023-05-01 .
  10. Web site: Mitchell J . Extraction of Frankincense Resins . Bangor University . 2023-05-01 . en.
  11. Al-Yasiry AR, Kiczorowska B . Frankincense--therapeutic properties . Postepy Higieny I Medycyny Doswiadczalnej . 70 . 380–391 . January 2016 . 27117114 . 10.5604/17322693.1200553 . free .
  12. Michie CA, Cooper E . Frankincense and myrrh as remedies in children . Journal of the Royal Society of Medicine . 84 . 10 . 602–605 . October 1991 . 1744842 . 1295557 . 10.1177/014107689108401011 .
  13. Baeten J, Deforce K, Challe S, De Vos D, Degryse P . Holy smoke in medieval funerary rites: chemical fingerprints of frankincense in southern Belgian incense burners . PLOS ONE . 9 . 11 . e113142 . 2014-11-12 . 25391130 . 4229304 . 10.1371/journal.pone.0113142 . 2014PLoSO...9k3142B . free .
  14. Web site: December 2013 . NMR Guidelines for ACS Journals . 23 May 2023 . American Chemical Society.
  15. Al-Shidhani S, Rehman NU, Mabood F, Al-Broumi M, Hussain H, Hussain J, Csuk R, Al-Harrasi A . 6 . Quantification of Incensole in Three Boswellia Species by NIR Spectroscopy Coupled with PLSR and Cross-Validation by HPLC . Phytochemical Analysis . 29 . 3 . 300–307 . May 2018 . 29314317 . 10.1002/pca.2743 . 2018PChAn..29..300A .
  16. Gebrehiwot K, Muys B, Haile M, Mitloehner R . December 2003 . Introducing Boswellia papyrifera (Del.) Hochst and its non-timber forest product, frankincense . International Forestry Review . 5 . 4 . 348–353 . 10.1505/ifor.5.4.348.22661 . 1465-5489.
  17. Moussaieff A, Shohami E, Kashman Y, Fride E, Schmitz ML, Renner F, Fiebich BL, Munoz E, Ben-Neriah Y, Mechoulam R . 6 . Incensole acetate, a novel anti-inflammatory compound isolated from Boswellia resin, inhibits nuclear factor-kappa B activation . Molecular Pharmacology . 72 . 6 . 1657–1664 . December 2007 . 17895408 . 10.1124/mol.107.038810 . 539345 .
  18. Book: Yang P, Zhu MX . TRPV3 . 2014 . Mammalian Transient Receptor Potential (TRP) Cation Channels: Volume I . Handbook of Experimental Pharmacology . 222 . 273–291 . Nilius B, Flockerzi V . Berlin, Heidelberg . Springer . en . 10.1007/978-3-642-54215-2_11 . 24756710 . 978-3-642-54215-2 .