Susceptibility of spores of the microsporidian Nosema algerae to sunlight and germicidal ultraviolet radiation

Spores of the microsporidian Nosema algerae exposed to 1, 2, and 4 hr of sunlight and 121 μW/cm² of germicidal ultraviolet light were fed to first-instar Anopheles albimanus. Twenty days after feeding, the incidence and intensity of infection (spores/mosquito) were recorded from adult mosquitoes. While sunlight-treated spores showed no significant decline in incidence of infection after 1-, 2-, and 4-hr exposures, intensity of infection decreased significantly after the 2- and 4-hr exposures. Incidence of infection of mosquitoes fed bactericidal ultraviolet light-treated spores declined 48.2, 76.2, and 99.9% after 1-, 2-, and 8-min exposures, respectively. Measured by intensity of infection, activity of bactericidal light-treated spores decreased 87.2% after 1 min, 91.7% after 2 min, and 99.9% after 8 min. Levels of radiation required to inactivate spores of N. algerae fell within the range reported for other Microsporidia.     

The preservation of infective spores of Octosporea muscaedomesticae in Phormia regina,of Nosema algerae in Anopheles stephensi,and of Nosema whitei in Tribolium castaneum by lyophilization

Infective spores of three species of microsporidia were subjected to the lyophilization process by employing varying media as cryoprotectants. The infectivity of the lyophilized spores was then tested against a standard fresh spore preparation in the appropriate host insect. Spores of Octosporea muscaedomesticae served as an experimental model and were rendered noninfective in host Phormia regina (Calliphoridae: Diptera) after lyophilization with the following cryoprotective agents: skim milk (12%), ascorbic acid (5%) combined with thiourea (5%), glycerol (10%), mesoinositol (5%), and equine serum. Spores of O. muscaedomesticae lyophilized or vacuum-dried in 50% sucrose as well as in the hosts' tissues remained highly infective for as long as 2 years at a dose of 10⁶ spores/fly and a trial length of 12 days. At a dose of 5 × 10⁴ spores/fly there was a slight decrease in infectivity of the spores which had been lyophilized in the host's abdomen after a 2-year storage period compared with that of fresh, nonlyophilized spores. Naked spores of Nosema algerae suspended in 50% sucrose and lyophilized produced infection in 50% of the host population of Anopheles stephensi (Culicidae: Diptera) compared with 70% infection produced by fresh non-lyophilized spores. Spores of Nosema whitei lyophilized within its host larva Tribolium castaneum (Tenebrionidae: Coleoptera) remained 100% infective at a dose of 5 × 10⁵ spores/gram diet. It is concluded that an aqueous solution of 50% sucrose and/or the host's tissues are excellent protectants for the cryogenic or vacuum-drying process of the above-named spores, and their protective function may apply also to other microsporidian species.     

Infection and development of Nosema bombycis (Microsporida: Protozoa) in a cell line of Antheraea eucalypti

Spores of Nosema bombycis derived from diseased insects were highly purified by Urografin density gradient centrifugation. Antheraea eucalypti cells were inoculated with the purified spores primed with 0.1 n KOH solution to start a continuous propagation of N. bombycis in cell culture. The first increase in the number of infected A. eucalypti cells was observed at 48 hr postinoculation, and it was caused by the secondary infective forms of N. bombycis. The secondary infective forms were produced during the course of sporoblast differentiation. The parasites in cell cultures divided synchronously until 36 hr postinoculation. Mature spores were observed initially 6 days postinoculation at 27°C. The infected cultures were subcultured extensively for more than 1 year with the addition of healthy A. eucalypti cells.     

Life History and Electron Microscopy of a Haplosporidian,Nephridiophaga blattellae (Crawley) n. comb., in the Malphigian Tubules of the German Cockroach,Blattella germanica (L.)*

SYNOPSIS. Rearing of cockroaches without sporozoan parasites of the Malpighian tubules permitted the 1st experimental infections reported for these organisms as well as study of the intracellular early stages of infection. Infectivity tests show that the route of invasion is peroral rather than transovarian; that fresh spores obtained from either the Malpighian tubules or the hindgut are infective; that fresh spores held in aqueous suspension for 36 hr are not infective; that all ages and both sexes of cockroaches are susceptible, although older cockroaches are more readily infected experimentally; that a single peroral dose of a few hundred spores is sufficient to produce infection; that the earliest signs of progressive infection in the Malpighian tubules appear 15 days after ingestion of spores; and that the infection, spread mainly by schizogony, is well established by 23 days. Spores are acid-fast. The PAS-positive spore membrane is not dissolved by 20-min treatment with hot KOH, but tests for chitin were inconclusive. The life history of the parasite is described. “Encapsulation” of the parasite has been observed. Electron microscope studies, the first reported for the class Haplosporea, show similarities of the cytoplasmic structure of this haplosporidian with that of some members of the sporozoan class Telosporea, though no specialized structures were seen. Finding of intracellular stages together with failure of interspecific infection attempts suggest that the microorganism should be placed in the genus Nephridiophaga Ivanic, 1937 with the specific name blattellae Crawley, 1905.     

Germination and outgrowth of Bacillus popilliae in hemolymph slide mounts

Cabbage looper hemolymph induced rapid germination and outgrowth of spores of Bacillus popilliae. Spores germinated within sporangia but outgrowth occurred from free released spores as well as from spores retained in sporangia. With 37°C, an alkaline pH, and tyrosinase, outgrowth resulted in 1 hr. Of six strains of milky disease bacteria tested, hemolymph mediated germination and outgrowth of only those which are infective perorally for European chafer larvae, indicating a potential use as a screening tool to assess virulence for the chafer.     

Persistence of spores of Pleistophora schubergi (Cnidospora: Microsporida) in the field,and their application in microbial control

Spores of Pleistophora schubergi, when applied to oak trees in the field at 2 × 10⁸ spores/ml with a uv protectant, “Shade,” infected 88% of Anisota senatoria larvae at 4 days after spray application. Spores without the uv protectant infected only 10% of the larvae at 4 days after application. When the spores were applied at the rate of 2 × 10⁸ and 2 × 10⁷ spores/ml in the field, 96 and 72% of the A. senatoria larvae and 100 and 100% of the Symmerista canicosta larvae were infected 14 days after spray application.     

The infection of nonmosquito hosts by injection with spores of the microsporidan Nosema algerae

Nosema algerae normally infects only mosquitoes by the per os route but developed in a number of different arthropods when spores were injected into the hemocoels. Representatives of other phyla were not infected when injected with N. algerae spores. Spores produced in these injected hosts were of normal size and were infectious when fed to mosquito larvae. Many more spores were produced in some of the injected hosts than were produced in the infected mosquitoes. One corn earworm larva produced as many spores as 2,000 mosquito larvae.     

Role of Dipicolinic Acid in Survival of Bacillus subtilis Spores Exposed to Artificial and Solar UV Radiation

Pyridine-2,6-dicarboxylic acid (dipicolinic acid [DPA]) constitutes approximately 10% of Bacillus subtilis spore dry weight and has been shown to play a significant role in the survival of B. subtilis spores exposed to wet heat and to 254-nm UV radiation in the laboratory. However, to date, no work has addressed the importance of DPA in the survival of spores exposed to environmentally relevant solar UV radiation. Air-dried films of spores containing DPA or lacking DPA due to a null mutation in the DPA synthetase operon dpaAB were assayed for their resistance to UV-C (254 nm), UV-B (290 to 320 nm), full-spectrum sunlight (290 to 400 nm), and sunlight from which the UV-B portion was filtered (325 to 400 nm). In all cases, air-dried DPA-less spores were significantly more UV sensitive than their isogenic DPA-containing counterparts. However, the degree of difference in UV resistance between the two strains was wavelength dependent, being greatest in response to radiation in the UV-B portion of the spectrum. In addition, the inactivation responses of DPA-containing and DPA-less spores also depended strongly upon whether spores were exposed to UV as air-dried films or in aqueous suspension. Spores lacking the gerA, gerB, and gerK nutrient germination pathways, and which therefore rely on chemical triggering of germination by the calcium chelate of DPA (Ca-DPA), were also more UV sensitive than wild-type spores to all wavelengths tested, suggesting that the Ca-DPA-mediated spore germination pathway may consist of a UV-sensitive component or components.     

The influence of storage temperature on spore viability of Mattesia trogodermae (Protozoa: Neogregarinida)

The viability of Mattesia trogodermae spores stored at different temperatures was assessed by the percentage infection induced in 30-day-old Trogoderma glabrum larvae. Exposure to 73°C and higher temperatures for 30 min was lethal to the spores. Spores stored at ?19°C survived better than those stored at 26.7°, 3.5°, or ?30°C.     

The influence of water on the resistance of spores to inactivation by gaseous ethylene oxide

Standardized conditions for exposure to ethylene oxide were used to evaluate the resistance of spores dried for various times at different relative humidities and temperatures. Spores dried under conditions of high humidity exhibited low resistance to the sterilant, the resistance increasing as the relative humidity (RH) was decreased. Increasing the temperature of drying amplified this effect by reducing the time required for equilibration to a specific RH. Spores dried over a desiccant at 37°C showed a slight rise followed by a fall in resistance. Spores maintained under these conditions for a long period of time increased in resistance. Spores rapidly dried by exposure to low RH, over a desiccant or at elevated temperature, dried unevenly resulting in a heterogeneous population with respect to ethylene oxide resistance. This was expressed as non-logarithmic survivor curves. The initial vacuum drawn influences resistance. The resistance of spores dried on aluminium foil increased as the pressure was reduced. The rate at which the pressure was reduced had little effect on resistance, except with highly desiccated spores. Dried spores held at different reduced pressures with humidification, showed no differences in resistance. The implications of these findings in relation to the operation of ethylene oxide sterilization cycles and the preparation and use of biological monitors is discussed.     

Inhibition of Ascosphaera apis by citral and geraniol

In vitro tests showed that citral and geraniol inhibited the fungus Ascosphaera apis which causes chalkbrood disease in the honeybee, Apis mellifera. The vapors of 5 μl of citral or 10 μl of geraniol per culture dish prevented vegetative growth. Daily applications of 30 μl of citral per dish killed sporulated cultures within 48 hr. However, A. apis spores in dried larval remains (mummies) survived 96-hr exposure to the vapors of 30 μl of citral per dish per day.Vapors of a geranic and nerolic acid mixture, 2-heptanone, isopentyl acetate, octanoic acid, and citronella and melissa oils were less inhibitory than citral or geraniol. Potassium sorbate, sodium propionate, and tetracycline had no inhibitory effect when placed on the culture medium. Remains of larvae killed by American foulbrood disease caused only a slight reduction in the growth of A. apis.     

The influence of water on the resistance of spores to inactivation by gaseous ethylene oxide

Standardized conditions for exposure to ethylene oxide were used to evaluate the resistance of spores dried for various times at different relative humidities and temperatures. Spores dried under conditions of high humidity exhibited low resistance to the sterilant, the resistance increasing as the relative humidity (RH) was decreased. Increasing the temperature of drying amplified this effect by reducing the time required for equilibration to a specific RH. Spores dried over a desiccant at 37 degrees C showed a slight rise followed by a fall in resistance. Spores maintained under these conditions for a long period of time increased in resistance. Spores rapidly dried by exposure to low RH, over a desiccant or at elevated temperature, dried unevenly resulting in a heterogeneous population with respect to ethylene oxide resistance. This was expressed as non-logarithmic survivor curves. The initial vacuum drawn influences resistance. The resistance of spores dried on aluminium foil increased as the pressure was reduced. The rate at which the pressure was reduced had little effect on resistance, except with highly desiccated spores. Dried spores held at different reduced pressures with humidification, showed no differences in resistance. The implications of these findings in relation to the operation of ethylene oxide sterilization cycles and the preparation and use of biological monitors is discussed.     

Inactivation of Bacillus anthracis Spores by Liquid Biocides in the Presence of Food Residue

Biocide inactivation of Bacillus anthracis spores in the presence of food residues after a 10-min treatment time was investigated. Spores of nonvirulent Bacillus anthracis strains 7702, ANR-1, and 9131 were mixed with water, flour paste, whole milk, or egg yolk emulsion and dried onto stainless-steel carriers. The carriers were exposed to various concentrations of peroxyacetic acid, sodium hypochlorite (NaOCl), or hydrogen peroxide (H₂O₂) for 10 min at 10, 20, or 30°C, after which time the survivors were quantified. The relationship between peroxyacetic acid concentration, H₂O₂ concentration, and spore inactivation followed a sigmoid curve that was accurately described using a four-parameter logistic model. At 20°C, the minimum concentrations of peroxyacetic acid, H₂O₂, and NaOCl (as total available chlorine) predicted to inactivate 6 log₁₀ CFU of B. anthracis spores with no food residue present were 1.05, 23.0, and 0.78%, respectively. At 10°C, sodium hypochlorite at 5% total available chlorine did not inactivate more than 4 log₁₀ CFU. The presence of the food residues had only a minimal effect on peroxyacetic acid and H₂O₂ sporicidal efficacy, but the efficacy of sodium hypochlorite was markedly inhibited by whole-milk and egg yolk residues. Sodium hypochlorite at 5% total available chlorine provided no greater than a 2-log₁₀ CFU reduction when spores were in the presence of egg yolk residue. This research provides new information regarding the usefulness of peroxygen biocides for B. anthracis spore inactivation when food residue is present. This work also provides guidance for adjusting decontamination procedures for food-soiled and cold surfaces.     

Effects of ultraviolet radiation and sunlight on the entomogenous nematode,Neoaplectana carpocapsae

Infective-stage juveniles of Neoaplectana carpocapsae were acutely sensitive to short uv radiation (254 nm) and natural sunlight. High nematode mortality, although delayed, accompanied uv exposure. Irradiation rapidly reduced nematode pathogenicity, so that nematodes exposed for 7 min were unable to cause lethal infections in Galleria mellonelia larvae. Moreover, the median survival time of Galleria larvae increased progressively as nematode exposure to uv was lengthened. Inhibition of nematode reproduction and development was noted at exposure periods longer than 2.45 and 5 min, respectively. However, irradiation did not appear to affect juvenile motility. Exposure to direct sunlight also reduced pathogenicity, in a range from 6.9 to 94.9% at 30 and 60 min of exposure, respectively. Long uv (366 nm) did not affect juveniles at the exposures tested.     

Dendritic cells endocytose Bacillus anthracis spores: implications for anthrax pathogenesis

Phagocytosis of inhaled Bacillus anthracis spores and subsequent trafficking to lymph nodes are decisive events in the progression of inhalational anthrax because they initiate germination and dissemination of spores. Found in high frequency throughout the respiratory track, dendritic cells (DCs) routinely take up foreign particles and migrate to lymph nodes. However, the participation of DCs in phagocytosis and dissemination of spores has not been investigated previously. We found that human DCs readily engulfed fully pathogenic Ames and attenuated B. anthracis spores predominately by coiling phagocytosis. Spores provoked a loss of tissue-retaining chemokine receptors (CCR2, CCR5) with a concurrent increase in lymph node homing receptors (CCR7, CD11c) on the membrane of DCs. After spore infection, immature DCs displayed a mature phenotype (CD83(bright), HLA-DR(bright), CD80(bright), CD86(bright), CD40(bright)) and enhanced costimulatory activity. Surprisingly, spores activated the MAPK cascade (ERK, p38) within 30 min and stimulated expression of several inflammatory response genes by 2 h. MAPK signaling was extinguished by 6 h infection, and there was a dramatic reduction of secreted TNF-alpha, IL-6, and IL-8 in the absence of DC death. This corresponded temporally with enzymatic cleavage of proximal MAPK signaling proteins (MEK-1, MEK-3, and MAP kinase kinase-4) and may indicate activity of anthrax lethal toxin. Taken together, these results suggest that B. anthracis may exploit DCs to facilitate infection.     

Phased infectivity in Heterorhabditis megidis: the effects of infection density in the parental host and filial generation

Entomopathogenic nematodes can develop through two or more generations in the cadavers of killed insect hosts. Non-feeding infective juveniles from each generation emerge and may spend prolonged periods searching for a new host. The infectivity of the infective juveniles of Heterorhabditis megidis varies with time after emergence and may not reach a maximum until several weeks have passed. 'Phased infectivity' hypotheses propose that this pattern is adaptive, tending to reduce competition in new hosts. Here we provide further evidence that infectivity is phased in H. megidis. In addition, we show that the basic pattern is modified by infection density in the parental host and by filial generation. Two general patterns were observed: first, infective juveniles that developed under the least crowded conditions (F(1) infective juveniles produced in hosts infected with 16 parent nematodes) reached maximum infectivity after only 15 days, compared to 27 or 39 days for infective juveniles that developed under more crowded conditions (F(1) produced in hosts infected with 103 or 424 parent nematodes or F(2) infective juveniles). Second, infective juveniles had lower infectivity overall when produced under the most crowded conditions (F(2) versus F(1); highest versus lowest infection density). We propose that while lower overall infectivity is a necessary consequence of limited resource availability during infective juvenile development, the difference in the timing of peak infectivity reflects a shift in the fitness gains associated with being maximally infective either 'early' or 'late'. F(1) infective juveniles emerge several days before F(2) infective juveniles, and we suggest that filial generation and infection density in the parental host function as indicators of the potential risk of competition within new hosts.     

Importance of spores,crystals, and δ-endotoxins in the pathogenicity of different varieties of Bacillus thuringiensis in Galleria mellonella and Pieris brassicae

Physical methods were used to produce spores containing impurities of 0.02–0.05% crystals and crystals containing impurities of 0.001–0.01% spores from cultures of Bacillus thuringiensis. In Galleria mellonella larvae, these preparations from varieties galleriae, aizawai, and wuhanensis were only moderately active compared to 1:1 mixtures of spores and crystals. Spores of an acrystalliferous aizawai mutant were inactive and did not contain a polypeptide of the same size as the potent M_r 138000 δ-endotoxin present in spores and crystals of all three wild-type strains. Thus, this polypeptide probably contributed to the moderate activity of wild-type spores. Spore impurities in the crystal preparation were killed by γ irradiation without harming the crystals. The crystals without live spores were virtually inactive (LC₅₀s, ca. 10¹⁰ crystals/g insect food). Addition of 10³ spores to 10⁸ crystals/g food (0.001% spores) increased the mortality of larvae from 0 to 36%, and addition of 10⁴ spores (0.01% spores) killed 64% larvae. Thus, the addition of low levels of spores increased the potency of crystals in G. mellonella from virtually zero to moderate levels, suggesting that the live spore impurities in the crystal preparations were responsible for the observed moderate potency of crystals before γ irradiation, a view supported by a reduction of potency of crystal preparations following admixture of streptomycin to the insect food. In contrast to the results with G. mellonella, crystals were ca. 30 times as active as spores in Pieris brassicae larvae. Many authors have found crystals purified by physical methods to be highly active in a range of lepidopterous hosts. The present work indicates that the role of the spore impurities in these species may need further investigation. Absence of live spores of B. thuringiensis may impair the control of some insect species feeding on spore-free products and on microorganisms or plants into which endotoxins have been introduced by genetic manipulation.     

Survival of Clostridium perfringens During Baking and Holding of Turkey Stuffing

Vegetative cells of three strains of Clostridium perfringens were used as inoculum for bread and onion stuffing for eight lightweight and eight heavyweight turkeys. When stuffed turkeys were refrigerated (5 ± 1 C for 24 ± 2 hr), a mean count of 580 vegetative cells of C. perfringens per gram of stuffing was reduced to undetectable levels (<6 per gram) in six of the eight. An inoculum of spores of the three strains used in a second series survived refrigerated holding with no change in numbers. During cooking of the stuffed turkeys in an oven at 94 C, numbers of vegetative cells fell steadily and numbers of spores remained constant or increased slightly (2 of 16 stuffings), until the temperature of the stuffing rose above that permitting growth. Viable C. perfringens cells were recovered from the stuffings at the end of cooking plus 1 hr for the group inoculated with the spore suspension. Storage of these stuffings resulted in marked reductions in numbers after 6 days at 5 ± 1 C and in increases after 24 ± 2 hr at 23 ± 1 C. Cells of a strain which produces spores not considered heat-resistant survived in stuffing in birds cooked to doneness in ovens at 94, 163, and 232 C. In accepted methods of cooking stuffed turkeys, C. perfringens contaminants may survive and create a hazard if subsequent storage is in a temperature range which permits their multiplication.     

Role of the Spore Coat Layers in Bacillus subtilis Spore Resistance to Hydrogen Peroxide, Artificial UV-C, UV-B, and Solar UV Radiation

Spores of Bacillus subtilis possess a thick protein coat that consists of an electron-dense outer coat layer and a lamellalike inner coat layer. The spore coat has been shown to confer resistance to lysozyme and other sporicidal substances. In this study, spore coat-defective mutants of B. subtilis (containing the gerE36 and/or cotE::cat mutation) were used to study the relative contributions of spore coat layers to spore resistance to hydrogen peroxide (H₂O₂) and various artificial and solar UV treatments. Spores of strains carrying mutations in gerE and/or cotE were very sensitive to lysozyme and to 5% H₂O₂, as were chemically decoated spores of the wild-type parental strain. Spores of all coat-defective strains were as resistant to 254-nm UV-C radiation as wild-type spores were. Spores possessing the gerE36 mutation were significantly more sensitive to artificial UV-B and solar UV radiation than wild-type spores were. In contrast, spores of strains possessing the cotE::cat mutation were significantly more resistant to all of the UV treatments used than wild-type spores were. Spores of strains carrying both the gerE36 and cotE::cat mutations behaved like gerE36 mutant spores. Our results indicate that the spore coat, particularly the inner coat layer, plays a role in spore resistance to environmentally relevant UV wavelengths.     

The Effects of Temperature on the Infectivity of Romanomermis culicivorax

The survival time (ST) of the preparasitic larvae of Rornanomermis culicivorax was determined by measuring motility at 1, 6, 12, 18, 21, 27, 30, and 37 C; the ST₅₀ at each of these temperatures was 2.3, 2.2, 2.0, 2.0, 1.7, 1.6, 0.9, and 0.7 days, respectively. About one-third of the preparasites infected first-instar larvae of Culex pipiens within 24 h at 27 C. The preparasites were infective at 12 to 33 C with the optimum infectivity at 21-33 C. Lower temperatures decreased the percent infectivity but increased the time that the nematodes remained infective. The time required for host infection increased as the preparasitic larvae aged at 15, 21, and 27 C.