Pseudomonas strains are some of the most active and dominant bacteria in the rhizosphere and have been intensively investigated as biocontrol agents. P. fluorescens, P. putida, and P. cepacia were the predominant focus of research for practical applications. The strains of Pseudomonas produce several kinds of antibiotics, such as pyrolnitrin, pyoluteorin, and phenezine-1-carboxylate, all of which are closely related to the suppression of plant diseases.

The use of the gram-positive Bacillus species as a biocontrol agent has been relatively rare and has been studied less intensively than that of the gram-negative bacteria. Bacillus subtilis is mainly studied and occasionally B. megaterium, B. cereus, B. pumilus, and B. polymyxa. As Bacillus spp. have the characteristics of omnipresence in soils, high thermal tolerance, rapid growth in liquid culture, ready formation of resistant spores, and are considered to be a safe biological agent, their potential as biocontrol agents is considered to be high. However, evaluation of the bacteria has focused primarily on the degree of disease suppression2–6. The population dynamics and mechanism of suppression to plant pathogens in soil by Bacillus spp. have not been extensively investigated.

B. subtilis produces several kinds of antibiotics, e.g., bacillomycin, iturin, mycosubtilin, bacilysin, fengycin, plipastatin, and mycobacillin. However, the bacteria require a suitable substrate for production of these materials in soil. Investigation of the control of Streptomyces scabies in potatoes by B. subtilis revealed that more antibiotic was produced when the bacteria were grown in a water extract of soybean (7). Furthermore, when this bacterium was added to soil, buildup of potato scab was prevented, presumably because the soybean substrate supported antibiotic production in soil by B. subtilis, thus enhancing its ability to control the specific disease. A root system includes a wide variety of different substances whose compositions vary with changes in the metabolic state of different parts of the root system. The changes can be influenced by outside effects on the plants. Once a root is invaded by a pathogen, significant changes in exudation occur. Such changes could convert the environment into one hostile to the biocontrol agent. Because antibiotic activity is so dependent on outside events, biocontrol through its effects is likely to be unsatisfactory and certainly unpredictable, unless strains of microorganisms can be manipulated to make the synthesis of antagonistic compounds less susceptible to changes in nutrient sources. In this book, Chapters 2 and 3 explain the production of antifungal substances—iturin, surfactin, and plipastatin—and some examples of plant test related with these substances in soil.

2,3-Dihydroxybenzoyl-glycine (2,3-DHBG) is known as only one siderophore produced by the gram-positive B. subtilis(8, 9). Bacterial siderophores are also known to have functions to help plant growth such as supplying iron via an iron-chelating function called the plant-growth-promoting rhizobacteria (PGPR) effect, which eventually leads to a decrease in disease occurrence. The strain of B. subtilis isolated in this study showed a wide suppressive spectrum on plant pathogens by producing antibiotics and 2,3-DHBG (Chapter 5). Gram-negative Escherichia coli produces a siderophore, enterobactin; and the E. coli mutant of entD-encoding enterobactin was complemented for enterobactin production by the sfp ⁰ gene of B. subtilis, which differs from sfp (surfactin production gene) by five base substitutions and one base insertion that truncated a 224-amino-acid residue in sfp to a 165-amino-acid residue. Similar complementation was found in the regulatory gene lpa-14 for the antibiotics iturin A and surfactin derived from a potential bacterial control agent of B. subtilis. The finding that B. subtilis produced not only antibiotics that suppress plant pathogens but also siderophores, and the regulation of these products by the gene lpa-14 indicates the possibility of enhanced effectiveness of biocontrol by the manipulation of the gene (Chapter 5).

Some antifungal peptides produced by Bacillus species are synthesized by multienzyme complexes via nonribosomal mechanisms, and the molecular organization of these peptide synthetases encoded by the bacterial operons has been well analyzed. However, no relation between the genetic information and the suppressive effect on plant pathogens in soil has been reported. One regulatory gene lpa-14, which is responsible for the production of antibiotics, was found to be closely involved in the bacterial suppressive function against a plant disease in soil (Chapter 5).