In some cases of natural phenols, they are present in vegetative
foliage to discourage
herbivory, such as in the case of
Western poison oak.
Role in soils In
soils, it is assumed that larger amounts of phenols are released from decomposing
plant litter rather than from throughfall in any natural plant community. Decomposition of dead plant material causes complex organic compounds to be slowly oxidized
lignin-like
humus or to break down into simpler forms (sugars and amino sugars, aliphatic and phenolic organic acids), which are further transformed into microbial biomass (microbial humus) or are reorganized, and further oxidized, into humic assemblages (
fulvic and
humic acids), which bind to
clay minerals and
metal hydroxides. There has been a long debate about the ability of plants to uptake humic substances from their root systems and to metabolize them. There is now a consensus about how humus plays a hormonal role rather than simply a nutritional role in plant physiology. In the soil, soluble phenols face four different fates. They might be degraded and mineralized as a carbon source by
heterotrophic microorganisms; they can be transformed into insoluble and recalcitrant
humic substances by polymerization and condensation reactions (with the contribution of soil organisms); they might adsorb to
clay minerals or form
chelates with aluminium or iron ions; or they might remain in dissolved form, leached by percolating water, and finally leave the ecosystem as part of
dissolved organic carbon (DOC).
Role in survival Phenolic compounds can act as protective agents, inhibitors, natural animal toxicants and pesticides against invading organisms, i.e. herbivores, nematodes, phytophagous insects, and fungal and bacterial pathogens. The scent and pigmentation conferred by other phenolics can attract symbiotic microbes, pollinators and animals that disperse fruits.
Defense against predators Volatile phenolic compounds are found in plant
resin where they may attract benefactors such as
parasitoids or
predators of the herbivores that attack the plant. In the kelp species
Alaria marginata, phenolics act as chemical defence against herbivores. In tropical
Sargassum and
Turbinaria species that are often preferentially consumed by
herbivorous fishes and
echinoids, there is a relatively low level of phenolics and tannins. Marine allelochemicals generally are present in greater quantity and diversity in tropical than in temperate regions. Marine algal phenolics have been reported as an apparent exception to this biogeographic trend. High phenolic concentrations occur in brown algae species (orders
Dictyotales and
Fucales) from both temperate and tropical regions, indicating that
latitude alone is not a reasonable predictor of plant phenolic concentrations.
Defense against infection In
Vitis vinifera grape,
trans-
resveratrol is a phytoalexin produced against the growth of fungal pathogens such as
Botrytis cinerea and
delta-viniferin is another grapevine
phytoalexin produced following
fungal infection by
Plasmopara viticola.
Pinosylvin is a pre-infectious
stilbenoid toxin (i.e. synthesized prior to infection), contrary to
phytoalexins, which are synthesized during infection. It is present in the
heartwood of
Pinaceae. It is a fungitoxin protecting the wood from
fungal infection.
Sakuranetin is a
flavanone, a type of flavonoid. It can be found in
Polymnia fruticosa and
rice, where it acts as a
phytoalexin against spore germination of
Pyricularia oryzae. In
Sorghum, the ''SbF3'H2'' 3'H2? --> gene, encoding a
flavonoid 3'-hydroxylase, seems to be expressed in
pathogen-specific 3-deoxyanthocyanidin
phytoalexins synthesis, for example in
Sorghum-Colletotrichum interactions.
6-Methoxymellein is a
dihydroisocoumarin and a
phytoalexin induced in carrot slices by
UV-C, that allows resistance to
Botrytis cinerea and other
microorganisms.
Danielone is a
phytoalexin found in the
papaya fruit. This compound showed high antifungal activity against
Colletotrichum gloesporioides, a pathogenic fungus of papaya. Stilbenes are produced in
Eucalyptus sideroxylon in case of pathogens attacks. Such compounds can be implied in the
hypersensitive response of plants. High levels of phenolics in some woods can explain their natural
preservation against rot. In plants,
VirA is a protein
histidine kinase which senses certain sugars and phenolic compounds. These compounds are typically found from wounded plants, and as a result VirA is used by
Agrobacterium tumefaciens to locate potential host organisms for infection.
Role in allelopathic interactions Natural phenols can be involved in
allelopathic interactions, for example in
soil or in water.
Juglone is an example of such a molecule inhibiting the growth of other plant species around walnut trees. The aquatic vascular plant
Myriophyllum spicatum produces
ellagic,
gallic and
pyrogallic acids and (+)-
catechin, allelopathic phenolic compounds inhibiting the growth of blue-green alga
Microcystis aeruginosa.
Acetosyringone has been best known for its involvement in plant-pathogen recognition, especially its role as a signal attracting and transforming unique, oncogenic bacteria in genus
Agrobacterium. The virA gene on the
Ti plasmid in the genome of
Agrobacterium tumefaciens and
Agrobacterium rhizogenes is used by these soil bacteria to infect plants, via its encoding for a receptor for acetosyringone and other phenolic phytochemicals exuded by plant wounds. This compound also allows higher transformation efficiency in plants, in A. tumefaciens mediated transformation procedures, and so is of importance in plant biotechnology. == Content in human food ==