Damascenone Explained

Damascenone should not be confused with Damascone.

Damascenones are a series of closely related chemical compounds that are components of a variety of essential oils. The damascenones belong to a family of chemicals known as rose ketones, which also includes damascones and ionones. beta-Damascenone is a major contributor to the aroma of roses, despite its very low concentration, and is an important fragrance chemical used in perfumery.[1]

The damascenones are derived from the degradation of carotenoids.[2]

In 2008, (E)-β-damascenone was identified as a primary odorant in Kentucky bourbon.[3]

Biosynthesis

The biosynthesis for β-damascenone begins with farnesyl pyrophosphate (FPP) and isopentenyl pyrophosphate (IPP) reacting to produce geranylgeranyl pyrophosphate (GGPP) Figure 1. Next two molecules of GGPP are condensed together to produce phytoene by removal of diphosphate and a proton shift catalyzed by the enzyme phytoene synthase (PSY). Phytoene then goes through a series of desaturation reactions using the enzyme phytoene desaturase (PDS) to produce phytofluene then ζ-carotene. Other enzymes have been found to catalyze this reaction including CrtI and CrtP.[4] The next series of desaturation reactions is catalyzed by the enzyme ζ-carotene desaturase (ZDS) to produce neurosporene followed by lycopene. Other enzymes that are able to catalyze this reaction include CtrI and CrtQ. Next lycopene goes through two cyclization reactions with the use of the enzyme lycopene β-cyclase first producing γ-carotene followed by the second cyclization producing β-carotene as shown in Figure 2. The mechanism for the cyclization of lycopene to β-carotene is shown in Scheme 2. Next β-carotene reacts with O2 and the enzyme β-carotene ring hydroxylase producing zeaxanthin.[5] Zeaxanthin then reacts with O2, NADPH (H+), and reduced ferredoxin [iron-sulfur] cluster in the presence of the enzyme zeaxanthin epoxidase (ZE) to produce antheraxanthin which reacts in a similar fashion to produce violaxanthin. Violaxanthin then reacts with the enzyme neoxanthin synthase to form neoxanthin the main precursor for β-damascenone as shown in Figure 3.[6] In order to generate β-damascenone from neoxanthin there are a few more modifications needed. First neoxanthin undergoes an oxidative cleavage to create the grasshopper ketone. The grasshopper ketone then undergoes a reduction to generate the allenic triol. At this stage there are two main pathways the allenic triol can take to produce the final product. The allenic triol can undergo a dehydration reaction to generate either the acetylenic diol or the allenic diol. Finally one last dehydration reaction of either the acetylenic diol or the allenic diol produces the final product β-damascenone as shown in Figure 4.[7] [8] The proposed mechanism for the conversion of the allenic triol to the acetylenic diol is shown in Scheme 3. The proposed mechanism for the conversion of the acetylenic diol to the final product is shown in Scheme 4. This mechanism is known as a Meyer-Schuster rearrangement.

See also

Notes and References

  1. http://www.leffingwell.com/rose.htm Rose (Rosa damascena)
  2. The Synthesis of Damascenone and beta-Damascone and the possible mechanism of their formation from carotenoids . Sachihiko Isoe . Shigeo Katsumura . Takeo Sakan . Helvetica Chimica Acta . 56 . 5 . 1514–1516 . 1973 . 10.1002/hlca.19730560508 .
  3. Characterization of the Most Odor-Active Compounds in an American Bourbon Whisky by Application of the Aroma Extract Dilution Analysis . LUIGI POISSON . PETER SCHIEBERLE . Journal of Agricultural and Food Chemistry . 56 . 14 . 5813–5819 . 2008 . 10.1021/jf800382m . 18570373 .
  4. BCarotenoids and their cleavage products: Biosynthesis and functions . Michael H. Walter . Dieter Strack . Nat. Prod. Rep. . 28 . 4 . 663–692 . 2011 . 10.1039/c0np00036a . 21321752 .
  5. The lycopene β-cyclase plays a significant role in provitamin A biosynthesis in wheat endosperm . Jian Zeng . Cheng Wang . Xi Chen . Mingli Zang . Cuihong Yuan . Xiatian Wang . Qiong Wang . Miao Li . Xiaoyan Li . Ling Chen . Kexiu Li . Junli Chang . Yuesheng Wang . Guangxia Yang . Guangyuan He . BMC Plant Biology . 15 . 112 . 112 . 2015 . 10.1186/s12870-015-0514-5 . 25943989 . 4433027 . free .
  6. Biosynthetic Pathway and Health Benefits of Fucoxanthin, an Algae-Specific Xanthophyll in Brown Seaweeds . Koji Mikami . Masashi Hosokawa . Int. J. Mol. Sci. . 14 . 7 . 13763–13781 . 2013 . 3742216 . 10.3390/ijms140713763 . 23820585. free .
  7. Thermal Oxidation of 9'-cis-Neoxanthin in a Model System Containing Peroxyacetic Acid Leads to Potent Odorant β-Damascenone . Yair Bezman . Itzhak Bilkis . Peter Winterhalter . Peter Fleischmann . Russell L. Rouseff . Susanne Baldermann . Michael Naim . Journal of Agricultural and Food Chemistry . 53 . 23 . 9199–9206 . 2005 . 16277423 . 10.1021/jf051330b .
  8. Book: Carotenoid Cleavage Products . Peter Winterhalter . Recep Gök . 1134 . 125–137 . 2013 . 10.1021/bk-2013-1134.ch011 . ACS Symposium Series . 978-0-8412-2778-1 . TDN and β-Damascenone: Two Important Carotenoid Metabolites in Wine .