Natural production Natural vanillin is extracted from the seed pods of
Vanilla planifolia, a
vining orchid native to Mexico, but now grown in tropical areas around the globe.
Madagascar is presently the largest producer of natural vanillin. , the β--glucoside of vanillin As harvested, the green seed pods contain vanillin in the form of
glucovanillin, its β--
glucoside; the green pods do not have the flavor or odor of vanilla. Vanillin is released from glucovanillin by the action of the enzyme
β-glucosidase during ripening and during the curing process. After being harvested, their flavor is developed by a months-long curing process, the details of which vary among vanilla-producing regions, but in broad terms it proceeds as follows: First, the seed pods are
blanched in hot water, to arrest the processes of the living plant tissues. Then, for 1–2 weeks, the pods are alternately sunned and sweated: during the day they are laid out in the sun, and each night wrapped in cloth and packed in airtight boxes to sweat. During this process, the pods become dark brown, and
enzymes in the pod release vanillin as the free molecule. Finally, the pods are dried and further aged for several months, during which time their flavors further develop. Several methods have been described for curing vanilla in days rather than months, although they have not been widely developed in the natural vanilla industry, with its focus on producing a premium product by established methods, rather than on innovations that might alter the product's flavor profile.
Biosynthesis Although the exact route of vanillin biosynthesis in
V. planifolia is currently unknown, several pathways are proposed for its biosynthesis. Vanillin biosynthesis is generally agreed to be part of the
phenylpropanoid pathway starting with -phenylalanine, which is deaminated by
phenylalanine ammonia lyase (PAL) to form t-
cinnamic acid. The
para position of the ring is then
hydroxylated by the
cytochrome P450 enzyme cinnamate 4-hydroxylase (C4H/P450) to create
p-coumaric acid. Then, in the proposed ferulate pathway, 4-hydroxycinnamoyl-CoA ligase (4CL) attaches
p-coumaric acid to
coenzyme A (CoA) to create
p-coumaroyl CoA.
Hydroxycinnamoyl transferase (HCT) then converts
p-coumaroyl CoA to 4-coumaroyl
shikimate/
quinate. This subsequently undergoes oxidation by the P450 enzyme coumaroyl ester 3'-hydroxylase (C3'H/P450) to give caffeoyl shikimate/quinate. HCT then exchanges the shikimate/quinate for CoA to create caffeoyl CoA, and 4CL removes CoA to afford caffeic acid. Caffeic acid then undergoes
methylation by caffeic acid O-
methyltransferase (COMT) to give ferulic acid. Finally, vanillin synthase hydratase/lyase (vp/VAN) catalyzes hydration of the double bond in ferulic acid followed by a retro-aldol elimination to afford vanillin. The remainder was produced by
chemical synthesis. Vanillin was first synthesized from eugenol (found in oil of clove) in 1874–75, less than 20 years after it was first identified and isolated. Vanillin was commercially produced from eugenol until the 1920s. Later it was synthesized from lignin-containing "brown liquor", a byproduct of the
sulfite process for making
wood pulp. At present, the most significant of these is the two-step process practiced by
Rhodia since the 1970s, in which guaiacol (
1) reacts with
glyoxylic acid by
electrophilic aromatic substitution. The resulting
vanillylmandelic acid (
2) is then converted by 4-hydroxy-3-methoxyphenylglyoxylic acid (
3) to vanillin (
4) by oxidative decarboxylation. According to
Scientific American, vanillin produced this way contains aromatic impurities that add strength and creaminess to its flavor. The biosynthetic process starts with glucose, or any sugar that can be converted into erythrose 4-phosphate (which leads to 3-dehydroshikimic acid). The end product is 98% pure and is also considered natural in the EU. Using
ferulic acid (a chemical found in rice) as an input and a specific non GMO species of
Amycolatopsis bacteria, vanillin can be produced. Many other bacteria, either GMO or non-GMO, can be used for the same purpose. However, because vanillin inhibits the growth of free-floating bacteria, yields have been low. This can be overcome through the formation of
biofilms, which has been done with the non-GMO
B. subtilis strain CCTCC M2011162. However, using ferulic acid as the starting material does not qualify for "natural ingredient" in the EU. The same has been reported for guaiacol and guaicyl lignin (from conifers). These starting materials do not qualify for "natural ingredient" in the EU. == Uses ==