Disease suppressive soils function to prevent the establishment of pathogens in the rhizosphere of plants. These soils develop through the establishment of beneficial microbes, known as

plant growth-promoting rhizobacteria Rhizobacteria are root-associated bacteria that can have a detrimental (parasitic varieties), neutral or beneficial effect on plant growth. The name comes from the Greek ''rhiza'', meaning root. The term usually refers to bacteria that form symbi ...

(PGPR) in the rhizosphere of plant roots. These mutualistic microbes function to increase plant health by fighting against harmful soil microbes either directly or indirectly. As beneficial bacteria occupy space around plant roots they outcompete harmful pathogens by releasing pathogenic suppressive metabolites.

PGPR and harmful soil microbes

Plant growth promoting rhizobacteria are bacteria that promote plant growth, through

fixing nitrogen Nitrogen fixation is a chemical process by which molecular nitrogen (), with a strong triple covalent bond, in the air is converted into ammonia () or related nitrogenous compounds, typically in soil or aquatic systems but also in industry. Atmos ...

, producing growth hormones, or even suppressing pathogens. A variety of PGPR genera provide a wide array of functions that directly improve plant health. Bacteria genera '' Rhizobium'' and ''

Mesorhizobium ''Mesorhizobium'' is a genus of Gram-negative soil bacteria. At least one, the nitrogen fixing species, ''Mesorhizobium loti'', forms symbiotic root nodules with plants in the genus '' Lotus''. Strain MAFF303099 of ''M. japonicum'' has been full ...

'' work to fix nitrogen into a usable form. '' Actinomyces'' and '' Azospirillum'' produce growth hormones that increase root growth and uptake of nutrients. While many of these genera increase plant health directly some PGPR promote plant health indirectly through pathogen suppression. Pathogenic fungi create a complex of

hyphae A hypha (; ) is a long, branching, filamentous structure of a fungus, oomycete, or actinobacterium. In most fungi, hyphae are the main mode of vegetative growth, and are collectively called a mycelium. Structure A hypha consists of one or ...

that migrate through the soil. When these fungi reach the rhizosphere they release enzymes that degrade the cell wall of plant root cells. This allows them to enter and infect the host plant and prevent the uptake of nutrients. Beneficial '' Pseudomonas'' and '' Bacillus'' produce fungal suppressing metabolites that break up this migrating fungal

. Over time, plants are able to create disease-suppressive soils in response to these pathogens through the increasing the abundance of these PGPR in their rhizosphere area.

Establishment of suppressive soils

Plants respond to pathogens by recruiting PGPR to their root rhizosphere from the bulk soil to fill in and prevent pathogen establishment. This ultimately leads to the development of disease-suppressive soils. PGPR are recruited through the natural release

plant exudates An exudate is a fluid emitted by an organism through pores or a wound, a process known as exuding or exudation. ''Exudate'' is derived from ''exude'' 'to ooze' from Latin ''exsūdāre'' 'to (ooze out) sweat' (''ex-'' 'out' and ''sūdāre'' 'to ...

from root cells as they push through the soil. Different species of plants release different exudates and therefore recruit different microbial communities to their rhizosphere from the microbes already present in the surrounding bulk soil. If a beneficial microbe genera is not present in a soil plants are not able to recruit it as a defense. Therefore, suppressive soils are a function of the microbes already present in a soil and able to be recruited. The creation of these soils must be done by increasing PGPR in the overall bulk soil. Specific plants are able to recruit beneficial bacteria through the secretion of different root exudates. A greater diversity of plants in a soil leads to a greater diversity of microbes in the rhizosphere and furthermore can lead to greater suppression of soil diseases. Management, such as informed crop rotation and

soil solarization Soil solarization is a non-chemical environmentally friendly method for controlling pests using solar power to increase the soil temperature to levels at which many soil-borne plant pathogens will be killed or greatly weakened. Soil solarization ...

, can create suppressive soils that naturally suppress pathogens.Peters, R. D., Sturz, A. V., Carter, M. R., & Sanderson, J. B. (2003). Developing disease-suppressive soils through crop rotation and tillage management practices. ''Soil and Tillage Research'', ''72''(2), 181-192.

References

{{reflist Soil Phytopathology