Production of heat-stable exotoxin by Bacillus thuringiensis and related bacteria

Heat-stable exotoxin production by 740 strains of Bacillus thuringiensis and related bacteria was investigated using the housefly, Musca domestica, from the following viewpoints: (1) the relation-ship between B. thuringiensis flagellar (H) serotypes and exotoxin production and (2) the exotoxin production by Bacillus species other than B. thuringiensis. Of 437 isolates belonging to 11 serotypes of B. thuringiensis which had been confirmed to produce parasporal inclusions, 35 isolates belonging to serotypes 1, 3a:3b, 4a:4c, and 10 produced heat-stable exotoxin. Exotoxin was not detected in the isolates of serotypes 3a, 4a:4b, 5a:5b, 5a:5c, 6, 7, and 8a:8b. No heat-stable exotoxin was demonstrated in 28 acrystalliferous isolates which possessed H antigens of B. thuringiensis serotypes 1, 3a, 4a:4b, 4a:4c, 5a:5c, 6, 7, 10, 11a:11c, and 12. A total of 270 B. cereus isolates which did not possess B. thuringiensis H antigen were examined and three isolates were found to produce heat-stable exotoxin. No heat-stable exotoxin was produced by B. subtilis (two strains), B. natto (one strain), and B. megaterium (two strains). These results indicate that the heat-stable exotoxin production in B. thuringiensis is a strain-specific property rather than a serotype(subspecies)-specific property.     

Larvicidal activity of Bacillus thuringiensis subsp. israelensis, serovar H14 in Aedes aegypti: Histopathological studies

Bacillus thuringiensis subsp. israelensis, serovar H14, when applied as a primary commercial powder, caused the rapid death of Aedes aegypti larvae. Mortality started 6 min after application of 4 μg/ml of the pathogen and reached a maximum 27 min later. When the LC₅₀ (10 ng/ml) was applied, mortality began after 37 min and reached a maximum 120 min later. Histopathological changes in B. thuringiensis israelensis-treated larvae could be observed only in the midgut and caeca. In B. thuringiensis israelensis-treated “dead larvae”, the epithelial layer is disorganized, most of the cells have disappeared and the peritrophic membrane is broken. The epithelium in the B. thuringiensis israelensis-treated “living larvae” still maintains its monolayer structure, but with marked cellular hypertrophy and vacuolized cytoplasm. Also, the “brush border” is thinner and disrupted. Based on the fact that mortality of A. aegypti is a quick process, and because the histopathological changes caused by B. thuringiensis israelensis are similar to those found in lepidopterous larvae treated with pure δ-endotoxin of other B. thuringiensis variants, it is suggested that larvicidal activity of B. thuringiensis israelensis in A. aegypti is due to its δ-endotoxin.     

Two new subspecies of Bacillus thuringiensis isolated in Japan: Bacillus thuringiensis subsp. kumamotoensis (serotype 18) and Bacillus thuringiensis subsp. tochigiensis (serotype 19)

Bacteriological and serological characteristics of three Bacillus thuringiensis isolates obtained in Japan were investigated. They formed typical rhomboidal parasporal inclusions but flagellar (H) antigens of these isolates were different from those of the known 17 H serotypes of B. thuringiensis. The three isolates were divided into two new serotypes (serotypes 18 and 19). The serotype 18 isolate (3–71) produced thermostable exotoxin and the inclusions of this isolate were toxic to larvae of the silkworm, Bombyx mori, but nontoxic to larvae of the mosquito, Aedes aegypti. The other isolate (119-72) belonging to serotype 18 produced inclusions nontoxic to larvae of B. mori and A. aegypti and did not produce thermostable exotoxin. However, other bacteriological properties of the isolate 119-72 were similar to those of the isolate 3–71. The serotype 19 isolate (117-72) produced inclusions nontoxic to larvae of B. mori and A. aegypti and did not produce thermostable exotoxin. Acid production from saccharose and the production of brownish purple pigment were observed in the two serotype 18 isolates, while neither of them was observed in the serotype 19 isolate. In other 29 biochemical properties tested, there was no difference among the three isolates. Based on these characteristics, the following two subspecies names are proposed: Bacillus thuringiensis subsp. kumamotoensis (serotype 18) for the type strain 3–71 and Bacillus thuringiensis subsp. tochigiensis (serotype 19) for the type strain 117-72.     

The fate of exotoxin of Bacillus thuringiensis in Galleria mellonella caterpillars

Three hours after parenteral administration of ³²P-labeled exotoxin of Bacillus thuringiensis to caterpillars of Galleria mellonella, 80% of the radioactivity was localized in the hemolymph in the form of the original exotoxin. The remaining radioactivity occurred in the organs of the caterpillar, especially in the spinning glands and the intestine. After peroral administration, the exotoxin does not pass the intestinal wall into the hemolymph to a measurable degree. In this case, the exotoxin is split in the intestinal wall and the products of ³²P reutilization have been found in the hemolymph. The mechanism of action of the exotoxin in the insect organism is discussed; presumably it depends on different ways of administration of the substance.     

Susceptibility of the spruce budworm, Choristoneura fumiferana, and the white-marked tussock moth, Orgyia leucostigmata, to Bacillus thuringiensis: Chemical insecticide combinations

Bacillus thuringiensis mixed with the organophosphate insecticides, fenitrothion (Sumithion), Gardona^®, and Orthene^®, or the synthetic pyrethroid, SBP 1382, was incorporated into synthetic diet and fed larvae of the spruce budworm, Choristoneura fumiferana, and the white-marked tussock moth, Orgyia leucostigma. Mortality was highest when larvae were fed combinations of low concentrations of the insecticides and low to moderate concentrations of the pathogen. The data indicated that applications of a B. thuringiensis dosage expected to produce about 45% mortality of third and fourth instar larvae of the spruce budworm combined with a dosage of fenitrothion causing about 40% mortality or a dosage of Orthene causing from 5 to 25% mortality should result in low budworm survival. With a B. thuringiensis dosage causing 20–60% mortality combined with a fenitrothion dosage causing 15–50% mortality or a sublethal dosage of Gardona, a low survival rate of young white-marked tussock moth larvae may be expected.     

Effect of incubation in natural and autoclaved soil upon potency and viability of Bacillus thuringiensis

Spores and parasporal crystals of a Bacillus thuringiensis var. aizawai H-serotype 7, strain HD137, streptomycin-resistant mutant, were added to normal and autoclaved aliquots of pH 5 soil incubated at 25°C and ?0.10 MPa water availability. Viable B. thuringiensis in soil samples were estimated by dilution-plating on a streptomycin-based medium, and combined spore and crystal insecticidal activity was bioassayed with larvae of Galleria mellonella. Populations of B. thuringiensis in both soil treatments suffered exponential rates of mortality, which were represented by segmented linear regression. Mortality was far greater in natural than autoclaved soil. Potency also fell in both soil treatments. This loss of potency was greater in natural soil, although the rates of potency loss in either soil treatment correlated poorly with the respective mortality rates of the B. thuringiensis populations, as potency losses were not exponential functions. The results suggest that the presence of indigenous microorganisms in natural soil accelerated the rate of mortality and loss of potency of B. thuringiensis.     

Immunochemical analysis of parasporal crystal digests of Bacillus thuringiensis as an index of insecticidal activity

An immunoelectrophoretic method is described for analyzing alkali parasporal crystal digests of Bacillus thuringiensis preparations (Dipel^TM). There were two distinct immunoprecipitate peaks (A and B) in the direction of the anode. The higher A peak had no correlation with the bioactivity of B. thuringiensis samples, whereas, the height of the B peak was directly proportional to the bioactivity. There was excellent agreement between the immunoassay and the bioassay of insecticidal potency in terms of international units.     

Comparative effects of spore-crystal complexes and thermostable exotoxins of six subspecies of Bacillus thuringiensis on Ostrinia nubilalis (Lepidoptera: Pyralidae)

The relative activities of spore-crystal complexes and thermostable exotoxin produced by six subspecies of Bacillus thuringiensis were investigated using larvae of the European corn borer, Ostrinia nubilalis. Bacillus thuringiensis subsp. kenyae, subsp. galleriae, and subsp. kurstaki produced spore-cystal complexes active against the borer. Bacillus thuringiensis subsp. thuringiensis and subsp. darmstadiensis produced thermostable exotoxins active against the borer. Only one subspecies, B. thuringiensis subsp. tolworthi, produced both a spore-crystal complex and a thermostable exotoxin active against corn borer larvaer.     

Development of Bacillus thuringiensis in Galleria mellonella larvae exposed to gamma radiation

A suspension of Bacillus thuringiensis was inoculated at 24 and 72 hr into the oral cavity of Galleria mellonella larvae following exposure to 20, 50, and 70 Kr of gamma radiation, respectively. The cytopathology was conducted after B. thuringiensis had developed for 3, 5, and 7 hr and after radiation damage had developed for 27, 29, 31, 75, 77, and 79 hr in the larvae exposed to 20, 50, and 70 Kr, respectively.B. thuringiensis spores appeared in the midgut lumen from 3 to 7 hr after inoculation of 20 Kr irradiated larvae. At 7 hr after B. thuringiensis infection, and 79 hr after 20 Kr irradiation, the following changes were seen: B. thuringiensis rods appeared adsorbed onto the walls of epithelial cells, a few spores appeared in hemolymph, epithelial cells developed vacuoles, and villi appeared detached from the basement membrane.Within a period ranging from 3 to 5 hr after infection, B. thuringiensis rods attacked vacuolated epithelial cells of most of the 50 and 70 Kr irradiated larvae. At 7 hr after infection and at 31 hr after 70 Kr irradiation, the spores reached the interior of some epithelial cells and were also seen concentrated near the basement membrane.In general, the midgut epithelial cells of the 70 Kr-irradiated groups of larvae appeared highly vacuolated, badly disrupted, and in most cases undistinguishable as a result of attack of B. thuringiensis.In short, B. thuringiensis did not show a characteristic pattern of pathology on 20 and 50 Kr-irradiated midgut cells. The problem of permeability of B. thuringiensis toxin into the irradiated cells needs further investigation.     

Conjugal transfer between Bacillus thuringiensis and Bacillus cereus strains is not directly correlated with growth of recipient strains

Bacillus thuringiensis and Bacillus cereus belong to the B. cereus species group. The two species share substantial chromosomal similarity and differ mostly in their plasmid content. The phylogenetic relationship between these species remains a matter of debate. There is genetic exchange both within and between these species, and current evidence indicates that insects are a particularly suitable environment for the growth of and genetic exchange between these species. We investigated the conjugation efficiency of B. thuringiensis var. kurstaki KT0 (pHT73-Em^R) as a donor and a B. thuringiensis and several B. cereus strains as recipients; we used one-recipient and two-recipient conjugal transfer systems in vitro (broth and filter) and in Bombyx mori larvae, and assessed multiplication following conjugation between Bacillus strains. The B. thuringiensis KT0 strain did not show preference for genetic exchange with the B. thuringiensis recipient strain over that with the B. cereus recipient strains. However, B. thuringiensis strains germinated and multiplied more efficiently than B. cereus strains in insect larvae and only B. thuringiensis maintained complete spore germination for at least 24 h in B. mori larvae. These findings show that there is no positive association between bacterial multiplication efficiency and conjugation ability in infected insects for the used strains.     

Persistence of Bacillus thuringiensis in foundation beeswax and beecomb in beehives for the control of Galleria mellonella

Beecomb was protected against wax moth attack by impregnating foundation beeswax with Bacillus thuringiensis. Bakthane, a serotype I product, gave good protection of broodcomb for 2 yr at 0.5% in wax and partial protection for 6 yr at 2%. The active component was exotoxin present at about 0.9% in Bakthane in a very insoluble state. No harm to the bees was detected, even when a partially purified preparation of exotoxin was used, but further tests on the leaching of pure exotoxin from comb into honey are required before the latter can be regarded as a practical method of wax moth control. The action of exotoxin on Galleria mellonella larvae was slower than that of the spore-crystal complex and less than that of exotoxin on some Diptera. Spores and crystals of serotype V were × 500 as potent in G. mellonella as those of serotype I and exotoxin on honey-rich artificial food in laboratory assays, but their activity deteriorated in the first hive trials with treated foundation wax. Prehive deterioration was due both to Teepol and soap in the liquid lubricating the wax mill rollers and to moist storage of the foundation. This deterioration was prevented by the use of Triton X-100 as lubricant, by drying the newly impregnated foundation wax and by storing it in dry conditions. This resulted in good protection of comb for one hive season by 1% of serotype V Thuricide in foundation wax. However, protection after two seasons varied, making the use of serotype V spores and crystals uneconomical for commercial practice, although safe for bee and man.     

Extrachromosomal DNA in Bacillus thuringiensis var. kurstaki, var. finitimus, var. sotto, and in Bacillus popilliae

Four entomopathogenic bacteria contained extrachromosomal deoxyribonucleic acid (DNA) molecules of various sizes. Bacillus thuringiensis var. kurstaki contained twelve elements banding on agarose gels that ranged from 0.74 to > 50 × 10⁶ daltons, three of which were giant extrachromosomal DNA elements. B. thuringiensis var. sotto contained one giant extrachromosomal DNA element with a molecular size of about 23.5 × 10⁶ daltons and two lesser elements of 0.80 and 0.62 × 10⁶ daltons. B. thuringiensis var. finitimus harbored two giant DNA elements corresponding to >50 × 10⁶ daltons and two lesser bands with relative small size (0.98 and 0.97 × 10⁶ daltons). B. popilliae contained no giant extrachromosomal DNA elements but did contain two smaller elements corresponding to 4.45 and 0.58 × 10⁶ daltons. The possible use of extrachromosomal DNA elements that prove to be autonomous replicons for recombinant DNA studies is discussed.     

Allelochemical induced stress: Effects of l-canavanine on the pathogenicity of Bacillus thuringiensis in Manduca sexta

Increased susceptibility of Manduca sexta to commercial formulations of the microbial insecticide, Bacillus thuringiensis, as evidenced by lower LD₅₀ and LT₅₀ values, was observed when M. sexta were reared on an artificial diet supplemented with a sublethal concentration (2.5 mm) of l-canavanine. At several dosages of B. thuringiensis, which were administered either by diet contamination or by per os forced feeding, a greater than 70% reduction (P < 0.05) occurred in the LT₅₀ response with canavanine-treated larvae. The LD₅₀ values also were lowered by canavanine treatment. This constitutes the first report of a plant allelochemical enhancing the effect of B. thuringiensis in vivo. It is suggested that canavanine enhances the effect of B. thuringiensis on gut permeability and active transport.     

Hemolymph responses in Heliothis zea to inoculation with Bacillus thuringiensis or Micrococcus lysodeikticus

Direct injection into the hemolymph of Heliothis zea of either an entomopathogen (Bacillus thuringiensis subsp. kurstaki) or a nonpathogen (Micrococcus lysodeikticus) is followed by a rapid phagocytosis and extensive removal of the organisms within 2 hr. The bacteria that survive this initial clearance initiate a new round of growth that is clearly evident 6–8 hr after injection. When the infecting organism is M. lysodeikticus, a second period of clearance occurs 8–12 hr after injection and nearly complete removal (many by lysis) is evident by the 12th hr. Larvae usually survive infection with this organism. When B. thuringiensis is the infecting organism, 60–80% of the phagocytized bacteria are lysed, however, the second wave of clearance seen with M. lysodeikticus does not occur; instead, the bacteria multiply extensively and death of the larvae results 12–16 hr after injection. This death does not appear to be caused either by crystalline protein or by the β-exotoxin. Analysis of hemolymph proteins using one-dimensional polyacrylamide gel electrophoresis indicated that although some quantitative changes were observed in some experiments, in the faster moving proteins when the infecting agent was B. thuringiensis, they were not consistent enough to support the idea that hemolymph proteins were either synthesized or used up during the time larvae were responding to the infectious agent. Dramatic changes were evident when the larvae were near death. No changes were ever observed when M. lysodeikticus was used as the infecting organism. A rapid response to infection using free spores of B. thuringiensis (sickness within 2–4 hr followed by death at 6–8 hr) may indicate that the spore germinating process is accompanied by release of a highly toxic material.     

Comparative analysis of the virulence of invertebrate and mammalian pathogenic bacteria in the oral insect infection model Galleria mellonella

Infection of Galleria mellonella by feeding a mixture of Bacillus thuringiensis spores or vegetative bacteria in association with the toxin Cry1C results in high levels of larval mortality. Under these conditions the toxin or bacteria have minimal effects on the larva when inoculated separately. In order to evaluate whether G. mellonella can function as an oral infection model for human and entomo-bacterial pathogens, we tested strains of Bacillus cereus, Bacillus anthracis, Enterococcus faecalis, Listeria monocytogenes, Pseudomonas aeruginosa and a Drosophila targeting Pseudomonas entomophila strain. Six B. cereus strains (5 diarrheal, 1 environmental isolate) were first screened in 2nd instar G. mellonella larvae by free ingestion and four of them were analyzed by force-feeding 5th instar larvae. The virulence of these B. cereus strains did not differ from the B. thuringiensis virulent reference strain 407Cry⁻ with the exception of strain D19 (NVH391/98) that showed a lower virulence. Following force-feeding, 5th instar G. mellonella larvae survived infection with B. anthracis, L. monocytogenes, E. faecalis and P. aeruginosa strains in contrast to the P. entomophila strain which led to high mortality even without Cry1C toxin co-ingestion. Thus, specific virulence factors adapted to the insect intestine might exist in B. thuringiensis/B. cereus and P. entomophila. This suggests a co-evolution between host and pathogens and supports the close links between B. thuringiensis and B. cereus and more distant links to their relative B. anthracis.     

Interactions between Bacillus thuringiensis subsp. kurstaki HD-1 and midgut bacteria in larvae of gypsy moth and spruce budworm

We examined interaction between Bacillus thuringiensis subsp. kurstaki HD-1 (Foray 48B) and larval midgut bacteria in two lepidopteran hosts, Lymantria dispar and Choristoneura fumiferana. The pathogen multiplied in either moribund (C. fumiferana) or dead (L. dispar) larvae, regardless of the presence of midgut bacteria. Inoculation of L. dispar resulted in a pronounced proliferation of enteric bacteria, which did not contribute to larval death because B. thuringiensis was able to kill larvae in absence of midgut bacteria. Sterile, aureomycin- or ampicillin-treated larvae were killed in a dose-dependent manner but there was no mortality among larvae treated with the antibiotic cocktail used by [Broderick et al., 2006] and [Broderick et al., 2009]. These results do not support an obligate role of midgut bacteria in insecticidal activity of HD-1. The outcome of experiments on the role of midgut bacteria may be more dependent on which bacterial species are dominant at the time of experimentation than on host species per se. The L. dispar cohorts used in our study had a microflora, that was dominated by Enterococcus and Staphylococcus and lacked Enterobacter. Another factor that can confound experimental results is the disk-feeding method for inoculation, which biases mortality estimates towards the least susceptible portion of the test population.     

Fermentation media and production of exotoxin by three varieties of Bacillus thuringiensis

The insecticidal activities of the exotoxin produced by three varieties of Bacillus thuringiensis grown in six fermentation media were determined by testing the supernatants against larvae of the house fly, Musca domestica, and the black cutworm, Agrotis ipsilon. The activities of the exotoxins from the isolates varied when they were grown in the same medium and also when they were grown in different media. When an isolate of B. thuringiensis var. thuringiensis, and of var. tolworthi were grown in proflo broth, the supernatants produced were more toxic to house fly than to black cutworm larvae, indicating the presence of more than one exotoxin. Autoclaving the supernatants for 15 and 30 min further demonstrated the presence of several exotoxins.     

UBER DEN BIOTEST VON BACILLUS THURINGIENSIS-EXOTOXIN MIT DROSOPHILA MELANOGASTER

Summary Larvae of Drosophila melanogaster (Meigen), placed as eggs on the substrate, are suitable for bioassay of the toxic qualities of the supernatant from culture media of Bacillus thuringiensis Berliner. Only supernatants of active strains of B. thuringiensis var. thuringiensis contained a thermostable exotoxin and, therefore, caused significant mortality. Supernatants prepared from cultures of other varieties of B. thuringiensis, however, as well as from cultures of Bacillus cereus had no effect (Tab. I). Pure preparations of the spore-endotoxin-complex of B. thuringiensis ded not kill larvae of Drosophila melanogaster even in doses of 0.16 per cent of the medium (Tab. II). According to the qualitative classification of commercial B. thuringiensis-preparations by Burgerjon, Biospor 2802 (Farbwerke Hoechst, Germany), belongs to group I, whereas Bakthane L-69 (Rohm & Haas, USA) is representative of group II.

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Über den Biotest von Bacillus thuringiensis-Exotoxin mit drosophila melanogaster

Zusammenfassung Zur Prüfung der toxischen Qualitäten von Kulturüberständen von Bacillus thuringiensis-Kulturen dienten Larven von Drosophila melanogaster. Es wurden abgezählte mengen von Eiern auf das kontaminierte Substrat aufgebracht und am Ende des Versuchs die entwickelten Imagines registriert. Nur Überstände aktiver Stämme von B. thuringiensis var. thuringingiensis enthielten ein thermostabiles Exotoxin und bewirkten eine entsprechende Mortalität. Kultur-überstände anderer Varietäten von B. thuringiensis wie auch von Bacillus cereus hatten keine Wirkung (Tab. I). Gereinigte Präparate des Sporen-Endotoxin-Komplexes von B. thuringiensis waren selbst in Dosen von 0,16% des Mediums unwirksam (Tab. II). Entsprechend der qualitativen Klassifikation von industriellen B. thuringiensis-Präparaten nach Burgerjon gehört Biospor 2802 (Farbwerke Hoechst, Deutschland) zur Gruppe I, während Bakthane L-69 (Rohm & Haas, USA) für die Gruppe II repräsentativ ist.

     

Investigations on cellular defense reactions with Galleria mellonella against Bacillus thuringiensis

In contrast to a great number of foreign particles (bacteria and inorganic materials), cells of some strains of Bacillus thuringiensis are not phagocytosed in the first hours after injection into the hemocoel of Galleria mellonella. This phenomenon is not caused by the production of β-exotoxin or exoenzymes, because heat-killed cells are not phagocytosed and the phagocytosis of latex particles is not prevented by the presence of living B. thuringiensis. The phagocytosis of heat-killed B. thuringiensis subtoxicus can be encouraged by treatment of the cells and by simultaneous injection of latex particles. A factor stimulating the phagocytosis is discussed. It is induced by the injection of phagocytosable latex particles into the hemocoel but not by injection of living or killed B. thuringiensis subtoxicus.     

Behavior of red wood ants (Hymenoptera,Formicidae) during interaction with different symbiont partners

A comparative analysis of the behavior of Formica polyctena Först during interaction with different symbionts (free-living aphids Aphis grossulariae Kalt. and hidden larvae of the sawfly Blasticotoma filiceti Klug) was carried out. Red wood ants demonstrate different levels of functional differentiation in relatively constant groups of foragers collecting honeydew. A deep “professional” specialization with clear division of a number of tasks among foragers was studied in groups of ants tending aphids. Four professional groups of foragers with different tasks were revealed: “shepherds,” “guards,” “transporters,” and “scouts” (or “coordinators”). The groups of foragers caring for sawfly larvae mainly consist of unspecialized ants. Only few ants (about 5%) remain on duty on the fern plant near B. filiceti larvae and protect the food resource from competitors, especially from other ants. In addition, the ants demonstrate simpler behavior while collecting the larval excretion, resembling that at the sugar feeders. On the whole, the behavior of red wood ants is rather flexible. The level of functional differentiation in groups of foragers collecting honeydew is determined not only by the colony size and requirements but by the nature of their interaction with trophobionts, particularly, by the possibility of direct contact.