|Posted on September 16, 2020 at 12:30 AM|
FUNGI Genus: Trichoderma
Fungi of the genus Trichoderma live in soils that are rich in organic plant matter. They can also establish symbiotic relationships with the roots of the plants growing in these soils. Numerous studies have shown the beneficial effects of Trichoderma, including:
Helping the plant to defend itself. Unlike animals, plants do not have the ability to produce antibodies to protect themselves against pathogens entering their organisms. However, they do produce other kinds of molecules, especially proteins and phytoalexins (substances with fungicidal and bactericidal properties) which help fight the effects of the pathogen. The plant starts to produce these substances when it detects that it is under attack from an insect or when it suffers damage from rodents or other herbivorous animals, for example.
The Trichoderma fungi secrete a series of substances that cause the plant to produce these defence proteins and phytoalexins even when they are not under attack by a parasite. Many phytopathogenic fungi produce enzymes that break down the cell walls of the plant they are infecting. As these cells decompose, this acts as a signal alerting the plant to the fact that it is under attack. The Trichoderma fungi produce enzymes, particularly cellulases, which break down organic matter (dead roots, remains of other plants, etc). The products of this enzymatic decomposition are very similar to those generated in a pathogen attack and they therefore replicate the signal, inducing the production of resistant substances.
Mycoparasitism is the ability of these fungi to grow and act as parasites on other fungi which may be plant pathogens. For example, some species of Trichoderma can be useful for fighting and preventing Rhizoctonia solani, a fungus that causes damping off and root rot. Because of this, Trichoderma are also sprayed on leaves to fight fungal diseases such as oidium and mildew. In addition, this mycoparasitism stimulates the plant’s defences, since the substances produced in the breakdown of the pathogenic fungus are very similar to those that serve as a signal to alert the plant. For example, chitosan, a component of the cell wall of the fungi that is not found in plants, triggers the production of a series of defensive substances.
They also promote the growth of the host plant more generally by improving the assimilation of certain nutrients.
Mycorrhizae are fungi that establish a symbiotic relationship with the roots of the plants in order to develop. Some edible fungi, including the extremely rare and valuable truffle, are mycorrhizae fungi that establish symbiotic relationships with the roots of different species, primarily hazel and oak. Depending on the way in which they colonize the root system, they can be classified as endomycorrhizae and ectomycorrhizae. In ectomycorrhizae, the mycelium only grows externally, surrounding the surface of the root or at most penetrating between the cells in the surface layers.
As secondary roots grow from these colonized roots, they are also enveloped in the mycelium of the fungus. The plant can use the mycelium, which extends beyond its root system, to gather nutrients lying beyond its reach.
In the case of the endomycorrhizae, the process of colonization involves penetrating the cells. There are various types of endomycorrhizae, but the most important ones from an agricultural point of view are the vesiculararbuscular mycorrhizae or VA M. They include Glomus, Gigaspora, Acaulospora and Sclerocystis.
In the symbiotic relationship, the plant provides the fungus with sugar from photoassimilates and the mycorrhizae provides nutrients which the plant either cannot assimilate itself or can only produce in very small quantities.
Phytoremediation refers to the use of plants to eliminate toxic substances from the soil. Mycorrhizae fungi have been used to promote these plants’ capacity to absorb certain toxic elements or aid its distribution through the plant. It has been shown, for example, that the symbiosis of the Glomus mycorrhizae with the roots of the hemp plant helps in the translocation of toxic metals from the roots to the shoots.
Plant associated micro organisms
Many phytopathogenic fungi produce enzymes that break down the cell walls of a plant that has been damaged by rodents, herbivorous animals or parasites. As these cells decompose, this acts as a signal alerting the plant to the fact that it is under attack. The Trichoderma fungi produce enzymes which break down organic matter. The products of this enzymatic decomposition are very similar to those generated in a pathogen attack. They replicate the signal and the production of a resistant substance.
Cyanobacteria are photosynthetic bacteria. Some enter into symbiosis with plants; these include the bacteria Anabaena azollae which establishes a symbiotic relationship with the aquatic fern Azolla. These bacteria are atmosphericnitrogen fixers and provide various stimulants such as phytohormones. The nitrogen fixed by the fern-bacteria symbiosis has been widely used for fertilizing paddy fields, with the ferns grown prior to planting the rice. As the rice grows and the ferns die, the accumulated nitrogen is released and can then be used by the rice plants.
Rhizobacteria are bacteria that colonize and develop in or near to the plant root system. They are the most abundant of all the micro-organisms in the rhizosphere. The positive effect of these bacteria on the colonized plants was first observed in ancient times, when growers discovered that crops could be improved by planting them in a field that had previously been used for growing legumes. More recently, various studies have demonstrated various properties of some rhizobacteria. These beneficial bacteria are known as plant growth-promoting rhizobacteria (PGPR).
The rhizobium-Leguminosae symbiosis was probably the first to be used by humans to improve crop yields. Growers also noticed that the fastest-growing and best-producing plants had protuberances on their roots, called nodules, which were much less common on other plants.
In 1888, the German researchers Hellriegel and Wilfarth showed that it was in these nodules that nitrogen accumulated. The Dutch scientist Beijirink subsequently isolated the bacteria in the nodules. They belong to the genus Rhizobium, which, through the action of nitrogenase enzymes, convert atmospheric nitrogen – which cannot be used directly by the plant – into ammonium that plants can assimilate easily. This transformation occurs inside the nodules, which contain a characteristic dense pinkish liquid. The relationship between Rhizobium and Leguminosae is said to be endophytic because the bacteria develop inside the host plant. Other endophytic bacteria that are also nitrogen fixers include Azetobactor diazotrophicus, which develops inside the sugar cane plant and spreads throughout its vascular system.
The actinomycete Frankia also forms nodules with nitrogen-fixing capacities in some trees and bushes of the genus Casuarina.
There are other bacteria that fix atmospheric nitrogen, colonizing the roots of non-leguminous plants. Unlike Rhizobium, they do not develop inside the tissues of the host but in the rhizosphere. This is true of bacteria in the genus Azospirillum, for example.
Other nitrogen-fixing bacteria do not develop inside plants or in the rhizosphere and are therefore not considered to be rhizobacteria. These include bacteria in the genus Azotobacter which feed off decomposing organic matter in the soil.
Converting phosphorus and iron into a soluble form
Like Trichoderma, there are rhizobacteria that have the capacity to mobilize inorganic phosphorus and iron found in the soil to form insoluble compounds. They include bacteria of the genera Bacillus, Pseudomonas, Rhizobium and Erwinia.
The production of useful active molecules
Phytohormones and growth stimulators. Many of these bacteria produce plant hormones (also known as phytohormones) such as natural auxins (indoleacetic acid), gibberellins and cytokinins. As a result, their presence or application can improve processes such as germination and rooting. One fungus that produces large quantities of auxins is Azospirillum sp.
These rhizobacteria do not cause the plant to produce phytoalexins or resistance proteins but they boost its production if the plant is attacked by a phytopathogenic organism.
They promote the symbiosis of the root with other fungi and rhizobacteria
Although PGPRs produce substances that prevent the development of certain micro-organisms in the soil, they can also sometimes aid their symbiosis. This is the case of the endomycorrhiza Glomus and the PGPR Bacillus subtilis.
They have an inhibiting effect on other pathogenic micro-organisms, and as such can be used as biological control agents
Antibiotic production. The production of antibiotic substances makes these bacteria ideal candidates for preventing root-rotting conditions such as dampingoff and even to fight air-borne fungi such as Botritis. Many rhizobacteria produce these kinds of antibiotic, some of which have fungicidal or antiviral properties. The rhizobacteria that produce this type of antibiotic are primarily of the genus Pseudomona and Bacillus. Some antibiotics, such as Mupirocina produced by p. fluorescens are widely used in medicine.
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