Simon Cotton
Uppingham School, Rutland, UK
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"In the Blue Ridge Mountains of Virginia "On the trail of the lonesome pine", |
Indeed. It's all down to isoprene and terpenes.
Isoprene is 2-methyl-1,3-butadiene.
Terpenes are naturally occurring compounds, derived from the 5-carbon alkene isoprene. They contain multiples of 5 carbon atoms - 10, 15, 20 and so on. Strictly, terpenes are hydrocarbons, but the word is also nowadays used to describe derivatives.
Terpene type | Number of isoprene units | Carbon atoms | Example |
---|---|---|---|
Monoterpene | 2 | 10 | menthol, camphor, limonene, pinene, thujone, nerol |
Sesquiterpene | 3 | 15 | farnesol, carophyllene |
Diterpene | 4 | 20 | phytol, Vitamin A |
Sesterpene | 5 | 25 | - |
Triterpene | 6 | 30 | squalene, lanosterol |
Tetraterpene | 8 | 40 | β-carotene (provitamin A) |
To attract insects to pollinate them. And, of course, to repel predators. Sometimes they are even more cunning, as there are some plants which, when fed on by an insect, release a molecule that attracts something that is a predator on the herbivore.
It comes down to natural air pollution - trees exhale organic molecules like pinene and other small terpenes, but especially isoprene. Isoprene is closely involved in production of the air pollutant, ozone. In addition, when it is oxidised by atmospheric ozone, ·OH, or NOx radicals, it forms aerosols that cause scattering of the sunlight; since the intensity of the scattering is proportional to 1/λ4, the short wavelengths are enhanced in the scattered light, making it look blue (Rayleigh scattering). The Blue Mountains north of Sydney, Australia (photo, below left) are another example. In this case, the main molecule responsible for the blue colour is eucalyptus oil (below, right), another isoprene-derived terpene.
Indeed, molecules like pinene are responsible for "pine" smells, too. But there is more to pinene than that. It's got the molecular formula C10H16, so that, as you might expect, it's rather flammable. That's why pine cones and Christmas trees burn well, given the chance; it is also why forest fires involving conifers can spread fast.
Limonene, menthol, geraniol, camphor, selinene, carophyllene, zingiberine, retinol and β-carotene are just a small sample of the thousands of terpenes that occur in nature.
In their structures, isoprene units are joined together head-to-tail. That is, C1 of the four-carbon chain of one isoprene unit is joined to C4 of another. See, for example, the structure of β-selenine, below, which is made up of 3 isoprene units.
However, isoprene itself is not involved in the biological synthesis. This is done starting with acetic acid; three of these molecules get used in forming mevalonic acid, which is converted into isopentenyl pyrophosphate. This can isomerise into dimethylallyl pyrophosphate.
Two of these then react together to form geranyl pyrophosphate, which is the precusor of all monoterpenes. This can react further with another molecule of isopentenyl pyrophosphate forming farnesyl pyrophosphate, which is the precursor of sesquiterpenes. Two farnesyl pyrophosphate molecules can couple to give squalene, the C30 precursor of triterpenes, and also of steroids.
Yes, and polymers.
Another important way in which isoprene units are joined together is in the formation of rubber.
Yes, natural latex, produced by rubber trees (e.g. Hevea brasiliensis) as a defence against wounding by insect predators, is a suspension of latex, designed to gum up the mouths of the predators. Rubber got its name from Joseph Priestley (the man who discovered oxygen) who noted, on April 15th 1770, "I have seen a substance excellently adapted to the purpose of wiping from paper the mark of black lead pencil" and called it 'rubber' because it rubbed out the pencil marks.
It consists of cis-1,4-polyisoprene molecules. This confers stretchiness on it (improved in the commercial material by cross-linking the chains with sulphur, in the process called vulcanisation). Gutta-percha, obtained in latex from other trees (such as Palaquium gutta, and other East Asian evergreens), is the trans-isomer, and not elastic. (Gutta-percha is often used as an insulating material for cables, not to mention golf-ball coverings). Chicle, used to make chewing gum, is a polymer with both cis- and trans- linkages.