being collected from a
tapped rubber tree. The
chemical elements of which plants are constructed—principally
carbon,
oxygen,
hydrogen,
nitrogen,
phosphorus,
sulfur, etc.—are the same as for all other life forms: animals, fungi,
bacteria and even
viruses. Only the details of their individual molecular structures vary. Despite this underlying similarity, plants produce a vast array of chemical compounds with unique properties which they use to cope with their environment.
Pigments are used by plants to absorb or detect light, and are extracted by humans for use in
dyes. Other plant products may be used for the manufacture of commercially important
rubber or
biofuel. Perhaps the most celebrated compounds from plants are those with
pharmacological activity, such as
salicylic acid from which
aspirin is made,
morphine, and
digoxin.
Drug companies spend billions of dollars each year researching plant compounds for potential medicinal benefits.
Constituent elements Plants require some
nutrients, such as
carbon and
nitrogen, in large quantities to survive. Some nutrients are termed
macronutrients, where the prefix
macro- (large) refers to the quantity needed, not the size of the nutrient particles themselves. Other nutrients, called
micronutrients, are required only in trace amounts for plants to remain healthy. Such micronutrients are usually absorbed as
ions dissolved in water taken from the soil, though
carnivorous plants acquire some of their micronutrients from captured prey. The following tables list
element nutrients essential to plants. Uses within plants are generalized.
Pigments molecule. gives these
pansies their dark purple pigmentation. Among the most important molecules for plant function are the
pigments. Plant pigments include a variety of different kinds of molecules, including
porphyrins,
carotenoids, and
anthocyanins. All
biological pigments selectively absorb certain
wavelengths of
light while
reflecting others. The light that is absorbed may be used by the plant to power
chemical reactions, while the reflected wavelengths of light determine the
color the pigment appears to the eye.
Chlorophyll is the primary pigment in plants; it is a
porphyrin that absorbs red and blue wavelengths of light while reflecting
green. It is the presence and relative abundance of chlorophyll that gives plants their green color. All land plants and
green algae possess two forms of this pigment: chlorophyll
a and chlorophyll
b.
Kelps,
diatoms, and other photosynthetic
heterokonts contain chlorophyll
c instead of
b,
red algae possess chlorophyll
a. All chlorophylls serve as the primary means plants use to intercept light to fuel
photosynthesis.
Carotenoids are red, orange, or yellow
tetraterpenoids. They function as accessory pigments in plants, helping to fuel
photosynthesis by gathering wavelengths of light not readily absorbed by chlorophyll. The most familiar carotenoids are
carotene (an orange pigment found in
carrots),
lutein (a yellow pigment found in fruits and vegetables), and
lycopene (the red pigment responsible for the color of
tomatoes). Carotenoids have been shown to act as
antioxidants and to promote healthy
eyesight in humans.
Anthocyanins (literally "flower blue") are
water-soluble flavonoid pigments that appear red to blue, according to
pH. They occur in all
tissues of higher plants, providing color in
leaves,
stems,
roots,
flowers, and
fruits, though not always in sufficient quantities to be noticeable. Anthocyanins are most visible in the
petals of flowers, where they may make up as much as 30% of the dry weight of the tissue. They are also responsible for the purple color seen on the underside of tropical shade plants such as
Tradescantia zebrina. In these plants, the anthocyanin catches light that has passed through the leaf and reflects it back towards regions bearing chlorophyll, in order to maximize the use of available light
Betalains are red or yellow pigments. Like anthocyanins they are water-soluble, but unlike anthocyanins they are
indole-derived compounds synthesized from
tyrosine. This class of pigments is found only in the
Caryophyllales (including
cactus and
amaranth), and never co-occur in plants with anthocyanins. Betalains are responsible for the deep red color of
beets, and are used commercially as food-coloring agents. Plant physiologists are uncertain of the function that betalains have in plants which possess them, but there is some preliminary evidence that they may have fungicidal properties.{{cite journal ==Signals and regulators==