The morphology and development of Nosema carpocapsae,a microsporidian pathogen of the codling moth,Cydia pomonella (Lepidoptera: Tortricidae) in New Zealand

The morphology of Nosema carpocapsae and its development in experimentally infected codling moth larvae are described. Spherical uninucleate meronts were the first stages. Nuclear division produced binucleate meronts which were the most abundant vegetative stage, although additional uninucleate and a few tetranucleate meronts were also observed at this time. All meronts were spherical and ranged from 2.8 to 5.8 μm in diameter. Uninucleate and binucleate fusiform sporonts then appeared followed by some tetranucleate and dividing forms. Oval sporoblasts developed after these and did not divide before maturing into spores. Sporonts were approximately 5.0 to 7.9 × 2.4 to 3.0 μm. Spores developed in all host tissues except the nervous tissue. The binucleate spores showed considerable variation in spore size, 2.4 to 3.9 × 1.3 to 3.1 μm (alcohol fixed, Giemsa stained). The polar filament was usually coiled 11 times (range 9 to 13) at an angle of 53° to the long axis of the spore. Its maximum observed length was 75 μm.     

Comparative virulence of Nosema plodiae and Nosema heterosporum in the Indian meal moth, Plodia interpunctella

When larvae of the Indian meal moth, Plodia interpunctella, were fed diets containing spores of Nosema plodiae, the number that survived to the adult stage decreased and the rate of adult emergence was retarded as the concentration of spores was increased; all surviving adults were infected. Also, when larvae were reared on diets containing spores of Nosema heterosporum, the number that survived to the adult stage decreased as the concentration of spores was increased; however, no relationship was apparent between concentration of spores and the rate of adult emergence. The LC₅₀'s of N. plodiae and N. heterosporum were 8.09 × 10⁶ and 4.52 × 10³ spores/g diet, respectively, which confirmed preliminary observations regarding the relative virulence of the two species of Nosema to Indian meal moth larvae.     

Foliar application ofNosema pyrausta for suppression of populations of European corn borer

In 1974, an application of the microsporidan,Nosema pyrausta (Paillot, 1927)Kotlan, 1928, with a back-pack type sprayer (22.5×10⁷ spores/plant) to whorl stage maize infested with European corn borers,Ostrinia nubilalis (Hübner) reduced the number of larvae/plant by 48.1% and produced an infection of 15.3×10⁴ spores/mg of larval weight in 62.1% of the collected larvae. In 1975, applications of 24.3×10⁷ spores/plant to similar maize, in 2 separate tests, reduced the number of larvae/plant by 18.8 and 43.8% and caused an infection of 14.3 and 19.1×10⁴ spores/mg of larval weight in 65.9 and 63.3% of the collected larvae. Also, in 1975, applications of 24.3×10⁷ spores/plant to pollen shedding maize in 2 separate tests reduced the number of larvae/plant by 17.2 and 14.1% and caused an infection of 24.3 and 27.2×10⁴ spores/mg of larval weight in 99.2 and 95.2% of the collected larvae.     

Impact of a novel species of Nosema on the southwestern corn borer (Lepidoptera: Crambidae)

A study was undertaken to elucidate the impact of an undescribed Nosema sp. on the southwestern corn borer (SWCB; Diatraea grandiosella Dyar). The Nosema sp. (isolate 506) included in the study was isolated from an overwintering SWCB larva in Mississippi. It was highly infectious per os, with a median infective dose of 2.0 x 10(3) spores per larva. Even at the highest dosage tested (10(7) spores per larva), minimal mortality (< or = 3%) was observed in infected larvae, pupae, and adults reared in the laboratory on an artificial diet. However, infected pupae (0- and 7-d-old) were smaller, and the time to adult eclosion from pupation was slightly increased. Furthermore, the number of eggs produced by infected SWCB female moths substantially decreased (32%), and this effect was most pronounced on day 2, when the greatest number of eggs were oviposited by infected and noninfected moths. For eggs produced by infected females mated with infected males, hatch was slightly decreased by 16 and 15% for eggs laid on days 2 and 3, respectively. In addition, egg hatch was reduced in eggs oviposited by noninfected females mated with infected males on day 3. A low prevalence of infection (< 6%) was observed in the F1 generation originating from infected females mating with noninfected males, from noninfected females mating with infected males, and from infected females mating with infected males. Nosema 506 spores were observed in the proximity of reproductive tissues of infected female and male moths. Spores also were detected on the chorion surface and within eggs laid by infected females. Furthermore, 1-11% of larvae hatching from surface-sterilized eggs were infected by Nosema 506 indicating a transovarial mechanism of transmission.     

The susceptibility of the pea moth, Cydia nigricana, to infection by the granulosis virus of the codling moth, Cydia pomonella

Laboratory studies demonstrated that neonate larvae of the pea moth, Cydia nigricana, are susceptible to infection with a granulosis virus (CpGV) isolated from the codling moth, Cydia pomonella. Comparative LC₅₀ values for C. nigricana and C. pomonella are 1.90 × 10⁵ and 1.54 × 10⁴ capsules/ml of diet, respectively. The virus extracted from CpGV-infected pea moth larvae is serologically related, and probably identical, to CpGV.     

Wolbachia sp. (Rickettsiales: Rickettsiaceae) a symbiont of the almond moth,Ephestia cautella: Ultrastructure and influence on host fertility

Wolbachia sp. is a maternally inherited symbiont of the almond moth, Ephestia cautella. It is transmitted through the cytoplasm of the egg and occurs normally in the gonads of all stages of the moth. The symbiont is responsible for reproductive cytoplasmic incompatibility between crosses of experimental laboratory strains of aposymbiotic female moths and symbiotic (normal) males. Although female moths were inseminated in laboratory tests, their eggs failed to hatch and exhibited no signs of embryonic development. The reciprocal cross, i.e., symbiotic female months × aposymbiotic males, produced normal progeny.The ultrastructure of Wolbachia was studied in sections of E. cautella larval testes. Symbionts, minute rod-shaped structures, were abundant in the cytoplasm of hypertrophied spermatids. There was no indication of deleterious influence of symbionts on sperm production or activity. Strains of Wolbachia occur in allopatric populations of insects where they may function as a genetic isolation mechanism. Microorganismal reproductive incompatibility has been suggested as a possible approach for insect control.     

Some factors affecting spore replication of Nosema algerae (Microspora,Nosematidae) in Pieris brassicae (Lepidoptera)

The production of Nosema algerae spores was examined in Pieris brassicae. Spore replication in the insect host followed a logistic pattern of development. The factors studied which affected spore production and replication were dose level (5 × 10², 5 × 10³, and 5 × 10⁴ spores per insect), larval instar (fourth and fifth), and cool pretreatment of the insects at 20°C prior to inoculation compared with a constant temperature of 26°C. A three-way analysis showed the interactions between these factors. The logistic pattern of spore replication was used to explain the results.     

Dosage-mortality studies with commercial Bacillus thuringiensis sprayed in a modified Potter's tower against some forest insects

Dosage-mortality tests were carried out with commercial Bacillus thuringiensis (B.T.) (Dipel)^® against various instars of the spruce budworm, Choristoneura fumiferana, the white-marked and Douglas fir tussock moths, Hemerocampa leucostigmata and Orgyia pseudotsugata, and the gypsy moth, Porthetria dispar. Dipel was applied as a dilute (10^?2) molasses suspension onto artificial diet surface in a spray tower designed to simulate aerial application. Probit analysis of the results showed that LD₅₀s expressed both in terms of gallons deposited per acre and as spores and crystals deposited per cm² increased with larval age for all species. The spruce budworm was the most sensitive to the bacteria, followed in decreasing order of sensitivity by the white-marked tussock moth, Douglas fir tussock moth, and the gypsy moth. The mean slopes for all instars of the four species were 1.6, 3.1, 2.6, and 2.2, respectively, indicating that precision-wise, the assay of B.T. on artificial medium was good. The relatively low slope for spruce budworm is explained by its peculiar feeding habit. Among all species tested, bacteria-treated larvae gained weight at a considerably reduced rate compared with untreated ones. Reduction in weight resulting from lowered feeding activity intensified as dosage rates increased. The implication of this in terms of mortality assessments in microbial control operations is discussed.It is suggested that 0.02 gallon (4 × 10⁶ International Units) of Dipel Molasses deposited per acre may achieve economic control of fourth- to sixth-instar budworm and first-to second-instar gypsy moths. A deposit rate for second- to fifth-instar white-marked or Douglas fir tussock moths appears to be in the vicinity of 0.01 gallon (2 × 10⁶ IU) per acre.     

Influence ofNosema bordati (Microsporida: Nosematidae) on the biological cycle ofChilo partellus (Lep: Pyralidae), a stem borer of cultivated graminae

The biological cycle ofChilo partellus (Swinhoe) was described on artificial diet. From egg to adult, it lasted 32 to 49 days with an average of 36.6 days. About 2,000 larvae from the 2^nd to the 5^th instars were artificially infected by ingestion with doses ofNosema bordati Goudegnon, varying from 2×10² to 2×10⁷ spores per ml. Only 72 survived (7.66 %) of these infected larvae.N. bordati, when present in the larvae, continued to multiply in the resulting pupae. The parasite affected the adults of this Pyralid reducing in a proportion of 5 the productivity of infected females and increasing the production of sterile eggs in the proportion of 8.     

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.     

Nosema whitei,a microsporidan pathogen of some species ofTribolium

The pathogenicity ofNosema whitei was studied using a dose-mortality technique; larvae ofTribolium castaneum were reared for the duration of each experiment in flour mixed with known numbers of spores. The susceptibility of each of the first 5 larval instars was compared. The LD₅₀ (for mortality after 20 days) increased consistently from the first instar (1.8×10⁶ spores/g) to the fifth instar (1.0×10¹⁰ spores/g). The slopes of the probit lines increased consistently as age increased (from b=1.1 to b=3.9). Two factors which reduce the development time ofT. castaneum, high temperature and high humidity, both reduced the pathogenicity ofN. whitei. Thus pathogenicity decreased as the temperature was increased fram 25°C (LD₅₀=4.2×10⁶) through 30°C (LD₅₀=1.3×10⁷) to 35°C (LD₅₀=3.2×10⁶), also pathogenicity decreased consistently as humidity was increased fram 10%, through 30, 50, 70% to 90% R.H. Adults, emerging fromNosema free larvae, became infected only when exposed to a very high dose (2×10¹⁰ spores/g for 14 days from the day of emergence). Infected larvae were treated for 1 hr. at 45°C in an attempt to cure the infection. The infected larvae were not cured, rather the treatment had an adverse alfect on their survival.

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Résumé La pathogénicité deNosema whitei a été étudiée en élevant des larves deT. castaneum dans de la farine mélangée à des quantités connues de spores. La sensibilité des larves diminue uniformément en fonction de l'age; La DL₅₀ varie de 1,8×10⁶/g (1^er stade) à 1,0×10¹⁰ spores/g (5^e stade). Deux facteurs, qui accélèrent le développement deT. castaneum, des températures et des humidités élevées, réduisent tous les deux la pathogénicité deN. whitei. Les adultes ne peuvent être infectés qu'en les exposant à la dose extrêmement élevée de 2×10¹⁰ spores/g. Un traitement par la chaleur (45°C pendant une heure) n'a pas réussi à guérir les larves.

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This work financed by a Science Research Council (U.K.) studentship is based on a thesis submitted for a degree of Ph. D. at the University of Newcastle-upon-Tyne.     

A laboratory evaluation of the pathogenicity of Bacillus popilliae var. rhopaea, the agent of milky disease in Rhopaea verreauxi (Coleoptera: Scarabaeidae)

Two methods of infection, i.e., feeding known numbers of spores and rearing larvae in contaminated peat, were used to bioassay the susceptibility of Rhopaea verreauxi to Bacillus popilliae var. rhopaea at 23°C. The susceptibility of the three larval instars was similar as measured by the ID₅₀ and IC₅₀ values. However, within an instar, newly molted larvae were less susceptible than mature larvae when infected by the contaminated peat method. It is suggested that this was due to reduced food intake. The range of ID₅₀ values for all bioassays with R. verreauxi larvae were 1.1 × 10⁷ to 4.0 × 10⁷ spores per larva, and IC₅₀ values were 3.4 × 10⁶ to 5.0 × 10⁷ spores per g of contaminated peat. The slope of the probit line was always low (0.6 to 1.8) except for young first-instar larvae infected by contaminated peat when the slope was 4.0. Disease per se did not affect food intake, though intake was reduced at high doses of contaminated peat. Young larvae often died without developing symptoms but, with increasing age, infected larvae were more likely to develop symptoms. Bioassays with Othnonius batesi and Rhopaea morbillosa indicated a much lower susceptibility per os than for R. verreauxi. It is concluded that the potential for using B. popilliae var. rhopaea to control R. verreauxi is high, but the bacillus is unlikely to be of value in control of O. batesi or R. morbillosa.     

In vivo propagation of a microsporidan pathogenic to insects

Equivalent numbers of spores were produced when the microsporidan Nosema necatrix was propagated in either Trichoplusia ni or Heliothis zea. Maximum spore production was obtained at an inoculum level of 1 × 10⁵ spores/ml. Larvae inoculated 5 days post-hatching contained 1.6 × 10⁹ spores/gram larva after an incubation period of 21 days. Temperature optima for the parasite are 21–26°C in both hosts.     

Vertical transmission of Nosema fumiferanae (Microsporidia: Nosematidae) and consequences for distribution, post-diapause emergence and dispersal of second-instar larvae of the spruce budworm, Choristoneura fumiferana (Clem.) (Lepidoptera: Tortricidae)

We examined vertical transmission of Nosema fumiferanae in the eastern spruce budworm, Choristoneura fumiferana (Clem.) (Lepidoptera: Tortricidae), and how it affects overwintering distribution and survival and spring emergence and dispersal of second-instar larvae in outbreak populations. Females containing 5.0 x 10(5) spores or more consistently produced 100% infected progeny. Transmission efficiency was still 50% at burdens as low as 0.2 x 10(5) spores per moth. Infection intensity in offspring increased with maternal spore load but became highly variable above 25 x 10(5) spores per female. Nosema multiplied in second instars for at least 1 month after they entered dormancy, regardless of temperature (2 degrees C versus 21 degrees C). Infection did not affect the distribution of overwintering larvae in a white spruce canopy. Dormancy survival between late-summer and the following spring was lower in families from infected females and was negatively correlated with larval infection intensity. Infection delayed larval emergence from hibernacula in the spring and resulted in delayed dispersal of emerged larvae, at least when parasite prevalence and infection intensities were high. Infected larvae were less successful in establishing feeding sites after dispersal. Our results underscore the potential of Nosema infection to negatively affect processes early in the budworm life cycle.     

Potential for controlling codling moth Cydia pomonella (Linnaeus) (Lepidoptera: Tortricidae) in Argentina using the sterile insect technique and egg parasitoids

Codling moth is the main pest affecting apples and pears worldwide. Most pest control strategies used against this insect have relied on the use of broad‐spectrum insecticides which have led to non‐desirable effects like pesticide resistance, residues in the environment, human health concerns and the reduction of access to international markets. Therefore, alternative pest control strategies that would result in sustainable fruit production systems while taking care of the environment are strongly promoted. The use of the sterile insect technique has proven to be a valuable pest control tactic within area‐wide integrated pest management strategies, and its synergistic effect for Lepidoptera pests when combined with other biological control tactics such as parasitoids has been documented. The purposes of this research were to evaluate the response of an Argentinean codling moth strain to a sub‐sterilizing radiation dose of 100 Gy and to assess the acceptability and suitability of sterile codling moth eggs by the egg parasitoids, Trichogramma cacoeciae (Marchal) and Trichogramma nerudai (Pintureau and Gerding). Irradiated female moths survived better than irradiated male moths and non‐irradiated male and female moths. Also, the fecundity of irradiated female moths was reduced by more than 30% as compared to non‐irradiated ones whereas their fertility was close to zero. The F₁ generation was male biased with a lower fertility (inherited sterility) than the parental generation. Trichogramma cacoeciae and T. nerudai parasitized both fertile and sterile eggs. However, there was a significant reduction in acceptability for sterile eggs. Trichogramma nerudai parasitized more eggs than T. cacoeciae, but egg acceptability for this species was proportionally lower than for T. cacoeciae especially on eggs oviposited by irradiated females. Development to adult of both parasitoids species was not substantially affected by the origin of the eggs and the wasps had acceptable levels of adult emergence, survival and fecundity. These results provided useful information on the potential for controlling the codling moth using egg parasitoids and the sterile insect technique in Argentina.     

Stored Bacillus popilliae spores and their infectivity against Popillia japonica larvae

Bacillus popilliae spores were stored for about 7 years under three separate conditions: frozen in sterile distilled water, smeared on glass microscope slides, and stored in loam soil at room temperature. In separate experiments, each of the 7-year-old preparations was fed to Popilla japonica larvae at concentrations of 10³, 10⁵, 10⁷, and 10⁹ spores/g of soil. A significant decrease in the percentage of larvae infected occurred in all of the aged spore tests. B. popilliae spores stored in soil, for the extended period, produced 3% larval infection only at the 10⁹ spores concentration; similar results were obtained from frozen spores. When P. japonica larvae were fed spores stored dried on slides, about 20% of the larvae developed milky disease. When aged frozen spores were artificially injected into larvae, 12% became infected at concentrations of 1 × 10⁶ spores/larvae; dried spores at the same concentration infected about 38% of the insect larvae. We conclude from these data that aged B. popilliae spores are significantly less infective against P. japonica larvae than young spores.     

Effects of microsporidan infection on larval trematodes: infection with Nosema strigeoideae or N. echinostomi

Microsporidan infection in larval trematodes is primarily an infection of the wall of the germinal sac (sporocyst or redia), spreading from there to the contained developing embryos, causing bloating, distortion, and destruction of the embryos. The end result of Nosema strigeoideae infection in strigeoids is a sporocyst filled with cellular debris, deformed cercariae, spores, etc. In echinostomes infected with Nosema echinostomi the rediae become solidly packed with spores confined within a reticular network which almost completely obliterates the cavity.It is suggested that these differences may be due to morphological differences in the larval trematodes.     

Insecticidal activity of spore-free mutants of Bacillus thuringiensis against the Indian meal moth and almond moth

Three oligosporogenic mutants of Bacillus thuringiensis were assayed for toxicity against larvae of the Indian meal moth, Plodia interpunctella, and the almond moth, Ephestia cautella. The results were compared with insecticidal activity obtained from the parent strain (HD-1) and two standard B. thuringiensis formulations (HD-1-S-1971 and HD-1-S-1980) against the same insect species. The toxicity of the sporeless mutant preparations was significantly diminished against the Indian meal moth (10- to 26-fold increase in LC₅₀) but exceeded the toxicity of the standards against the almond moth. The toxicities of the B. thuringiensis preparations toward the Indian meal moth were consistent with the number of spores in the test samples, but spores did not contribute to toxicity to E. cautella larvae. A rationale for basing dosage on soluble protein was demonstrated for use in situations where spores are not a contributing factor in toxicity.     

Infectivity of a microsporidium of mosquitoes (Nosema algerae) to larval stages of Schistosoma mansoni in Biomphalaria glabrata

Lai P. F. and Canning E. U. 1980. Infectivity of a microsporidium of mosquitoes (Nosema algerae) to larval stages of Schistosoma mansoni in Biomphalaria glabrata. International Journal for Parasitology10: 293–301. Nosema algerae derived from a closed colony of Anopheles stephensi was fed to Biomphalaria glabrata infected with Schistosoma mansoni. Mother and daughter sporocysts became hyperinfected but the snail tissues remained free of the microsporidia except for rare small aggregates of spores. These lay close to the sites occupied by mother or daughter sporocysts and were probably liberated from them. Irrespective of dose, fewer snails contained infected sporocysts when spores were given at 7 days post-miracidial infection than when given at 14 days. These periods corresponded respectively to stages when mother sporocysts only or daughter sporocysts as well were present in the snails. Infection of the sporocysts began in the tegumental cells, spread to the brood chamber and ultimately to the cercariae themselves. Heavily infected sporocysts contained fewer developing embryos. Doses of 10⁶ and 10⁷ spores/snail caused significant depression of cercaria output when given at 14 days but not at 7 days.     

Occurrence and effects of Nosema fumiferanae infections on adult spruce budworm caught above and within the forest canopy

1 Nosema fumiferanae infections in populations of both sexes of spruce budworm Choristoneura fumiferana moths, collected live above the forest canopy (canopy moths), within the tree crown (crown moths) and in drop trays (dead moths), were examined over a 5‐year period in New Brunswick, Canada. 2 The incidence of infection and of moderate–heavy infections in canopy and crown moths of both sexes increased concomitantly with moth eclosion, indicating that N. fumiferanae retards larval/pupal development, with infected moths, particularly those having higher disease loads, emerging later in the season. 3 Infection rates differed among canopy, crown, and dead female, but not male, moths. Canopy (i.e. emigrating) females had a lower incidence of infection, lower incidence of moderate–heavy infections, and had longer forewings and higher dry weights, than crown females. These results suggest that N. fumiferanae infections negatively affect aspects of female, but not male, flight performance. Regardless of infection, forewing length and dry weight of both canopy and crown females declined over the moth flight period, but infected females in both moth types were smaller than their uninfected counterparts. Forewing lengths and dry weights of moderately–heavily infected females were most severely affected. 4 Despite high annual infection rates in parents, only a small percentage of offspring (second‐instar larvae) that established feeding sites each spring were infected, indicating that high rates of horizontal transmission occurred annually throughout the larval period. 5 The present study indicates that whether N. fumiferanae infections are a debilitating sublethal factor in spruce budworm populations depends more on the disease load than on the overall incidence of infection. The potential importance of N. fumiferanae infections on various fitness parameters related to host dispersal is discussed.