Constitutive and induced defenses Plant defenses can be classified as constitutive or induced. Constitutive defenses are always present, while induced defenses are produced or mobilized to the site where a plant is injured. There is wide variation in the composition and concentration of constitutive defenses; these range from mechanical defenses to digestibility reducers and toxins. Many external mechanical defenses and quantitative defenses are constitutive, as they require large amounts of resources to produce and are costly to mobilize. A variety of molecular and biochemical approaches are used to determine the mechanisms of constitutive and induced defensive responses. Induced defenses include secondary metabolites and morphological and physiological changes. An advantage of inducible, as opposed to constitutive defenses, is that they are only produced when needed, and are therefore potentially less costly, especially when herbivory is variable. and
plant-induced systemic resistance.
Chemical defenses , genus
Diospyros, has a high
tannin content which gives immature fruit, seen above, an
astringent and
bitter flavor. The evolution of chemical defenses in plants is linked to the emergence of chemical substances that are not involved in the essential photosynthetic and metabolic activities. These substances,
secondary metabolites, are organic compounds that are not directly involved in the normal growth, development or reproduction of organisms, and often produced as by-products during the synthesis of primary metabolic products. Examples of these byproducts include phenolics, flavonoids, and tannins. Although these secondary metabolites have been thought to play a major role in defenses against herbivores, a meta-analysis of recent relevant studies has suggested that they have either a more minimal (when compared to other non-secondary metabolites, such as primary chemistry and physiology) or more complex involvement in defense. Plants can communicate through the air. Pheromone release and other scents can be detected by leaves and regulate plant immune response. In other words, plants produce volatile organic compounds (VOC) to warn other plants of danger and change their behavioral state to better respond to threats and survival. These warning signals produced by infected neighboring trees allow the undamaged trees to activate the necessary defense mechanisms. Within the plant itself, it transmits warning, nonvolatile signals as well as airborne signals to surrounding undamaged trees to strengthen their defense/immune system. For instance, poplar and sugar maple trees demonstrated that they received tannins from nearby damaged trees. The injury by herbivores induces the release of linolenic acid and other enzymatic reactions in an octadecanoid cascade, leading to the synthesis of jasmonic acid, a hormone which plays a central role in regulating immune responses. Jasmonic acid induces the release of VOCs and EFN which attract parasitic wasps and predatory mites to detect and feed on herbivores. These volatile organic compounds can also be released to other nearby plants to be prepared for the potential threats. The volatile compounds emitted by plants are easily detected by third trophic level organisms as these signals are unique to herbivore damage. Salicylic acid is a phytohormone that is one of the essential hormones for regulating plants' immune systems. This hormone then signals to increase the production of tree chemicals called tannins within its leaves.
Alkaloids are derived from various
amino acids. Over 3,000 alkaloids are known, including
nicotine,
caffeine,
morphine,
cocaine,
colchicine,
ergolines,
strychnine, and
quinine. Alkaloids have
pharmacological effects on humans and other animals. Some alkaloids can inhibit or activate
enzymes, or alter
carbohydrate and fat storage by inhibiting the formation
phosphodiester bonds involved in their breakdown. Certain alkaloids bind to
nucleic acids and can inhibit synthesis of proteins and affect
DNA repair mechanisms. Alkaloids can also affect
cell membrane and
cytoskeletal structure causing the cells to weaken, collapse, or leak, and can affect
nerve transmission. Although alkaloids act on a diversity of metabolic systems in humans and other animals, they almost uniformly invoke an aversively
bitter taste.
Cyanogenic glycosides are stored in inactive forms in plant
vacuoles. They become toxic when herbivores eat the plant and break cell membranes allowing the glycosides to come into contact with
enzymes in the
cytoplasm releasing
hydrogen cyanide which blocks cellular respiration.
Glucosinolates are activated in much the same way as cyanogenic glucosides, and the products can cause
gastroenteritis, salivation, diarrhea, and irritation of the mouth. Upon tissue disruption they get into contact with β-glucosidases from the chloroplasts, which enzymatically release the toxic aglucones. Whereas some benzoxazinoids are constitutively present, others are only synthesized following herbivore infestation, and thus, considered
inducible plant defenses against herbivory. The
terpenoids, sometimes referred to as isoprenoids, are organic chemicals similar to
terpenes, derived from five-carbon
isoprene units. There are over 10,000 known types of terpenoids. Most are multicyclic structures which differ from one another in both functional groups, and in basic carbon skeletons. Monoterpenoids, containing 2 isoprene units, are
volatile essential oils such as
citronella,
limonene,
menthol,
camphor, and
pinene. Diterpenoids, 4 isoprene units, are widely distributed in
latex and
resins, and can be quite toxic. Diterpenes are responsible for making
Rhododendron leaves poisonous. Plant
steroids and
sterols are also produced from terpenoid precursors, including
vitamin D,
glycosides (such as
digitalis) and
saponins (which lyse
red blood cells of herbivores). Phenolics, sometimes called
phenols, consist of an
aromatic 6-carbon ring bonded to a
hydroxy group. Some phenols have
antiseptic properties, while others disrupt
endocrine activity. Phenolics range from simple
tannins to the more complex
flavonoids that give plants much of their red, blue, yellow, and white pigments. Complex phenolics called
polyphenols are capable of producing many different types of effects on humans, including
antioxidant properties. Some examples of phenolics used for defense in plants are:
lignin,
silymarin and
cannabinoids.
Condensed tannins, polymers composed of 2 to 50 (or more) flavonoid molecules, inhibit herbivore digestion by binding to consumed plant proteins and making them more difficult for animals to digest, and by interfering with protein absorption and
digestive enzymes. In addition, some plants use
fatty acid derivatives,
amino acids and even
peptides as defenses. The
cholinergic toxin
cicutoxin of
water hemlock is a
polyyne derived from the fatty acid metabolism.
Oxalyldiaminopropionic acid is a neurotoxic amino acid produced as a defensive metabolite in the grass pea (
Lathyrus sativus). The synthesis of
fluoroacetate in several plants is an example of the use of small molecules to disrupt the metabolism of herbivores, in this case the
citric acid cycle. Plants interact by producing
allelochemicals which interfere with the growth of other plants (allelopathy). These have a role in plant defense and may be used to suppress competitors such as weeds of crops. A result may be larger plants better able to survive damage by herbivores.
Enzymes Premier examples are substances activated by the
enzyme myrosinase. This enzyme converts
glucosinolates to various compounds that are toxic to
herbivorous insects. One product of this enzyme is
allyl isothiocyanate, the pungent ingredient in
horseradish sauces. The myrosinase is released only upon crushing the flesh of horseradish. Since allyl isothiocyanate is harmful to the plant as well as the insect, it is stored in the harmless form of the glucosinolate, separate from the myrosinase enzyme.
Mechanical defenses plant serve as a mechanical defense against herbivory. See the review of mechanical defenses by Lucas
et al., 2000, which remains relevant and well regarded in the subject . Many plants have external structural defenses that discourage herbivory. Structural defenses can be described as morphological or physical traits that give the plant a fitness advantage by deterring herbivores from feeding. Depending on the herbivore's physical characteristics (i.e. size and defensive armor), plant structural defenses on stems and leaves can deter, injure, or kill the grazer. Some defensive compounds are produced internally but are released onto the plant's surface; for example,
resins,
lignins,
silica, and wax cover the
epidermis of
terrestrial plants and alter the texture of the plant tissue. The leaves of
holly plants, for instance, are very smooth and slippery making feeding difficult. Some plants produce
gummosis or sap that traps insects.
Spines and thorns A plant's leaves and stem may be covered with sharp prickles, spines, thorns or
trichomes- hairs on the leaf often with barbs, sometimes containing
irritants or poisons. Plant structural features such as spines, thorns and
awns reduce feeding by large ungulate herbivores (e.g.
kudu,
impala, and
goats) by restricting the herbivores' feeding rate, or by wearing down the molars. Trichomes are frequently associated with lower rates of plant tissue digestion by insect herbivores. Similarly, African
Acacia trees have long spines low in the canopy, but very short spines in the high canopy, which is comparatively safe from herbivores such as giraffes. s protect their fruit by surrounding it with multiple layers of armor. Trees such as palms protect their fruit by multiple layers of armor, needing efficient tools to break through to the seed contents. Some plants, notably the
grasses, use indigestible
silica (and many plants use other relatively indigestible materials such as
lignin) to defend themselves against vertebrate and invertebrate herbivores. Plants take up
silicon from the soil and deposit it in their tissues in the form of solid silica
phytoliths. These mechanically reduce the digestibility of plant tissue, causing rapid wear to vertebrate teeth and to insect mandibles, and are effective against herbivores above and below ground. The mechanism may offer future sustainable pest-control strategies.
Thigmonastic movements Thigmonastic movements, those that occur in response to touch, are used as a defense in some plants. The leaves of the
sensitive plant,
Mimosa pudica, close up rapidly in response to direct touch, vibration, or even electrical and thermal stimuli. The
proximate cause of this mechanical response is an abrupt change in the
turgor pressure in the
pulvini at the base of leaves resulting from
osmotic phenomena. This is then spread via both electrical and chemical means through the plant; only a single leaflet need be disturbed. This response lowers the surface area available to herbivores, which are presented with the underside of each leaflet, and results in a wilted appearance. It may also physically dislodge small herbivores, such as insects. Many of these plants have evolved in nutrient-poor soil, and must procure nutrients from other sources. They use insects and small birds as a way to gain the minerals they need through carnivory. Carnivorous plants do not use carnivory as defense, but to get the nutrients they need.
Mimicry and camouflage '', a pebble plant,
camouflaged as small stones, reducing the chance that it will be seen by herbivores Some plants make use of various forms of
mimicry to reduce herbivory. One mechanism is to mimic the presence of insect eggs on their leaves, dissuading insect species from laying their eggs there. Because female butterflies are less likely to lay their eggs on plants that already have butterfly eggs, some species of
neotropical vines of the
genus Passiflora (passion flowers) make use of
Gilbertian mimicry: they possess physical structures resembling the yellow eggs of
Heliconius butterflies on their leaves, which discourage
oviposition by butterflies. Other plants make use of
Batesian mimicry, with structures that imitate thorns or other objects to dissuade herbivores directly. A further approach is
camouflage; the vine
Boquila trifoliolata mimics the leaves of its host plant, while the pebble plant
Lithops makes itself hard to spot among the stones of the Southern African environment.
Indirect defenses '' are hollow and offer shelter for ants, which indirectly protect the plant against herbivores. Another category of plant defenses are those features that indirectly protect the plant by enhancing the probability of attracting the
natural enemies of herbivores. Such an arrangement is
mutualistic, in this case of the "
enemy of my enemy" variety. One such feature is the use of
semiochemicals given off by plants. Semiochemicals are a group of
volatile organic compounds involved in interactions between organisms. One group of semiochemicals are
allelochemicals; consisting of
allomones, which play a defensive role in
interspecies communication, and
kairomones, which are used by members of higher
trophic levels to locate food sources. When a plant is attacked it releases allelochemics containing an abnormal ratio of these s (HIPVs). Predators sense these volatiles as food cues, attracting them to the damaged plant, and to feeding herbivores. The subsequent reduction in the number of herbivores confers a
fitness benefit to the plant and demonstrates the indirect defensive capabilities of semiochemicals. Induced volatiles have drawbacks, however; some studies suggest that these volatiles attract herbivores. for
symbiotic ants in swollen hollow spines of
Vachellia seyal acacia Plants sometimes provide housing and food items for natural enemies of herbivores, known as "biotic" defense mechanisms, to maintain their presence. For example, trees from the genus
Macaranga have adapted their thin stem walls to create
domatia, ideal housing for ants (genus
Crematogaster), which, in turn, protect the plant from herbivores. In addition to providing housing, the plant also provides the ant with its exclusive food source; from the food bodies produced by the plant. Similarly, several
Acacia tree species have developed stipular spines (direct defenses) that are swollen at the base, forming a hollow structure that provides housing for protective ants. These
Acacia trees also produce
nectar in
extrafloral nectaries on their leaves as food for the ants.
Plant use of endophytic fungi in defense is common. Most plants have
endophytes, microbial organisms that live within them. While some cause disease, others protect plants from herbivores and
pathogenic microbes. Endophytes can help the plant by producing toxins harmful to other organisms that would attack the plant, such as alkaloid producing
fungi which are common in grasses such as
tall fescue (
Festuca arundinacea), which is infected by
Neotyphodium coenophialum. Trees of the same species form alliances with other tree species to improve their survival rate. They communicate and have dependent relationships through connections below the soil called underground mycorrhiza networks, which allows them to share water/nutrients and various signals for predatory attacks while also protecting the immune system. Within a forest of trees, the ones getting attacked send communication distress signals that alerts neighboring trees to alter their behavior (defense). Other responses such as the change of leaf
colors prior to fall have also been suggested as adaptations that may help undermine the camouflage of herbivores.
Autumn leaf color has also been suggested to act as an
honest warning signal of defensive commitment towards insect pests that migrate to the trees in autumn. ==Costs and benefits==