Effects of a novel microsporidium on the black vine weevil, Otiorhynchus sulcatus (F.) (Coleoptera: Curculionidae)

A newly discovered microsporidium infecting the black vine weevil, Otiorhynchus sulcatus (F.) (Coleoptera: Curculionidae), provisionally placed in the genus Canningia, was studied to determine its impact on O. sulcatus. O. sulcatus populations from several locations were sampled and evaluated for microsporidiosis. A very low prevalence of the disease was observed in all locations surveyed (<3.0%). Laboratory studies were conducted by orally exposing both larvae and adults of O. sulcatus to varying concentrations of Canningia sp. spores. Larval bioassays at a variety of dosages (0, 10, etc.) were performed to evaluate pathogen infectivity, larval survival and growth. Adult bioassays (dosages: 0, 10, etc.) were performed to evaluate longevity, fecundity and mechanisms of vertical pathogen transmission. Larvae and adults were infected in all spore treatments. Larval growth was significantly reduced at dosages above 10 spores/larva. Adults infected at all dosages experienced high levels of mortality and fecundity was reduced to zero. Greenhouse trials were performed to determine if larvae feeding in soil acquired infections when spores were topically applied as a drench application (0, 10⁵, 10⁶, 10⁷ spores/pot). Established larvae feeding on plant roots in pots developed infections when exposed to drench treatments of 10⁶ and 10⁷ spores/pot after 14-21 days. Canningia sp. is an acute pathogen of O. sulcatus infective to both larvae and adults. Topically applied spores also infected larvae feeding on roots in soilless potting media, suggesting the possibility of using this pathogen in a microbial control program.     

Quantifying horizontal transmission of Nosema lymantriae, a microsporidian pathogen of the gypsy moth, Lymantria dispar (Lep., Lymantriidae) in field cage studies

Nosema lymantriae is a microsporidian pathogen of the gypsy moth, Lymantria dispar that has been documented to be at least partially responsible for the collapse of L. dispar outbreak populations in Europe. To quantify horizontal transmission of this pathogen under field conditions we performed caged-tree experiments that varied (1) the density of the pathogen through the introduction of laboratory-infected larvae, and (2) the total time that susceptible (test) larvae were exposed to these infected larvae. The time frame of the experiments extended from the early phase of colonization of the target tissues by the microsporidium to the onset of pathogen-induced mortality or pupation of test larvae. Upon termination of each experiment, the prevalence of infection in test larvae was evaluated. In the experiments performed over a range of pathogen densities, infection of test larvae increased with increasing density of inoculated larvae, from 14.2 ± 3.5% at density of 10 inoculated per 100 larvae to 36.7 ± 5.7% at 30 inoculated per 100 larvae. At higher densities, percent infection in test larvae appeared to level off (35.7 ± 5.5% at 50 inoculated per 100 larvae). When larval exposure to the pathogen was varied, transmission of N. lymantriae did not occur within the first 15 d post-inoculation (dpi) (11 d post-exposure of test larvae to inoculated larvae). We found the first infected test larvae in samples taken 20 dpi (16 d post-exposure). Transmission increased over time; in the cages sampled 25 dpi (21 d post-exposure), Nosema prevalence in test larvae ranged from 20.6% to 39.2%.     

Relevance of genomic imprinting to human diseases.

The existence of functional differences between parts of the maternal and paternal genome has been demonstrated. The control of gene expression through genomic imprinting plays a significant role in normal developmental processes in mammals and is also instrumental in several human pathological conditions.     

New insect system for testing antibiotics

New and efficient methods to screen antibiotics are needed to counter increased antibiotic resistance in pathogens and the emergence of new diseases. Here we report a new insect model for screening antibiotics in vivo using the grasshopper Romalea microptera. The system is inexpensive, efficient, and flexible, avoids animal-welfare problems, and can be used to test against most major pathogenic groups. We employed this system to test 11 commercial antibiotics against a pathogenic Encephalitozoon species (Microsporidia). Oral treatment with fumagillin or thiabendazole significantly reduced pathogen spore counts, whereas spore counts of grasshoppers fed with albendazole, ampicillin, chloramphenicol, griseofulvin, metronidazole, sulfadimethoxine, or tetracycline were not significantly different from the infected controls. Quinine produced a distinct, but nonsignificant, reduction in spores, and streptomycin a nonsignificant increase in spores. Although 2 antibiotics significantly reduced spore counts, in no case was the pathogen totally eliminated. This study demonstrates the validity of this system as a method to screen antibiotics. It also corroborates the difficulty researchers and physicians have had in treating microsporidia infections, and suggests that quinine and related alkaloid compounds should be further examined as possible therapeutic agents against this group of ubiquitous pathogens. In addition, streptomycin and related compounds should be tested to determine if this widely used antibiotic enhances microsporidiosis.     

Interspecific geographic distribution and variation of the pathogens Nosema bombi and Crithidia species in United States bumble bee populations

Several bumble bee (Bombus) species in North America have undergone range reductions and rapid declines in relative abundance. Pathogens have been suggested as causal factors, however, baseline data on pathogen distributions in a large number of bumble bee species have not been available to test this hypothesis. In a nationwide survey of the US, nearly 10,000 specimens of 36 bumble bee species collected at 284 sites were evaluated for the presence and prevalence of two known Bombus pathogens, the microsporidium Nosema bombi and trypanosomes in the genus Crithidia. Prevalence of Crithidia was ≤10% for all host species examined but was recorded from 21% of surveyed sites. Crithidia was isolated from 15 of the 36 Bombus species screened, and were most commonly recovered from Bombus bifarius, Bombus bimaculatus, Bombus impatiens and Bombus mixtus. Nosema bombi was isolated from 22 of the 36 US Bombus species collected. Only one species with more than 50 sampled bees, Bombus appositus, was free of the pathogen; whereas, prevalence was highest in Bombus occidentalis and Bombus pensylvanicus, two species that are reportedly undergoing population declines in North America. A variant of a tetranucleotide repeat in the internal transcribed spacer (ITS) of the N. bombi rRNA gene, thus far not reported from European isolates, was isolated from ten US Bombus hosts, appearing in varying ratios in different host species. Given the genetic similarity of the rRNA gene of N. bombi sampled in Europe and North America to date, the presence of a unique isolate in US bumble could reveal one or more native North American strains and indicate that N. bombi is enzootic across the Holarctic Region, exhibiting some genetic isolation.     

Studies on the impact of two Nosema isolates from Bulgaria on the gypsy moth (Lymantria dispar L.)

We investigated host-parasite interactions of two Nosema-type microsporidian isolates recovered from populations of Lymantria dispar L. in northwestern Bulgaria, one near Veslec and one near Levishte. Bioassay studies produced information on development, stage specific mortality, pupation, and adult eclosion of infected individuals. Horizontal transmission of the two isolates was investigated in a second set of experiments. At dosages ranging from 2 x 10(2) to 5 x 10(4) spores/microl, the infection rates varied between 77 and 100% for the isolate from Veslec and between 92 and 99% for the Levishte isolate. The Veslec isolate caused a slightly higher mortality rate and the median time to death was shorter compared to the isolate from Levishte. The total mortality for both isolates varied between 79 and 99%, independent of spore dosages. A lower relative growth rate was recorded for male and female L. dispar larvae infected with either isolate during the third larval instar and a higher relative growth rate during the fourth instar compared to the control groups. Pupal weight did not differ significantly among females, but male infected pupae were heavier than the controls. Nosema sp. [Veslec] was as efficiently transmitted as Nosema sp. [Levishte]; 42% of the susceptible larvae became infected with the Veslec isolate when uninfected larvae were exposed to infected larvae; 43% of larvae became infected with the Nosema sp. [Levishte]. The latency period varied between 7 and 8 days for both isolates.