A protocol for generating germ-free Heligmosomoides polygyrus bakeri larvae for gnotobiotic helminth infection studies.

The microbes indigenous to helminth species are a major obstacle to deciphering host-parasite interactions. Repurposing a system of reversible bacterial colonization, we have generated germ-free Heligomosomoides polygyrus bakeri (Hpb) larvae that maintain the sterility of axenic mice upon infection. This protocol provides a valuable tool for controlled studies of helminth-microbiota-immune interactions.

Infection with a small intestinal helminth, Heligmosomoides polygyrus bakeri, consistently alters microbial communities throughout the murine small and large intestine.

Increasing evidence suggests that intestinal helminth infection can alter intestinal microbial communities with important impacts on the mammalian host. However, all of the studies to date utilize different techniques to study the microbiome and access different sites of the intestine with little consistency noted between studies. In the present study, we set out to perform a comprehensive analysis of the impact of intestinal helminth infection on the mammalian intestinal bacterial microbiome. For this purpose, we investigated the impact of experimental infection using the natural murine small intestinal helminth, Heligmosomoides polygyrus bakeri and examined possible alterations in both the mucous and luminal bacterial communities along the entire small and large intestine. We also explored the impact of common experimental variables including the parasite batch and pre-infection microbiome, on the outcome of helminth-bacterial interactions. This work provides evidence that helminth infection reproducibly alters intestinal microbial communities, with an impact of infection noted along the entire length of the intestine. Although the exact nature of helminth-induced alterations to the intestinal microbiome differed depending on the microbiome community structure present prior to infection, changes extended well beyond the introduction of new bacterial species by the infecting larvae. Moreover, striking similarities between different experiments were noted, including the consistent outgrowth of a bacterium belonging to the Peptostreptococcaceae family throughout the intestine.

Generating super-shedders: co-infection increases bacterial load and egg production of a gastrointestinal helminth.

Co-infection by multiple parasites is common within individuals. Interactions between co-infecting parasites include resource competition, direct competition and immune-mediated interactions and each are likely to alter the dynamics of single parasites. We posit that co-infection is a driver of variation in parasite establishment and growth, ultimately altering the production of parasite transmission stages. To test this hypothesis, three different treatment groups of laboratory mice were infected with the gastrointestinal helminth Heligmosomoides polygyrus, the respiratory bacterial pathogen Bordetella bronchiseptica lux(+) or co-infected with both parasites. To follow co-infection simultaneously, self-bioluminescent bacteria were used to quantify infection in vivo and in real-time, while helminth egg production was monitored in real-time using faecal samples. Co-infection resulted in high bacterial loads early in the infection (within the first 5 days) that could cause host mortality. Co-infection also produced helminth 'super-shedders'; individuals that chronically shed the helminth eggs in larger than average numbers. Our study shows that co-infection may be one of the underlying mechanisms for the often-observed high variance in parasite load and shedding rates, and should thus be taken into consideration for disease management and control. Further, using self-bioluminescent bacterial reporters allowed quantification of the progression of infection within the whole animal of the same individuals at a fine temporal scale (daily) and significantly reduced the number of animals used (by 85%) compared with experiments that do not use in vivo techniques. Thus, we present bioluminescent imaging as a novel, non-invasive tool offering great potential to be taken forward into other applications of infectious disease ecology.

Attempts to establish RNA interference in the parasitic nematode Heligmosomoides polygyrus.

To analyze the potential of RNA interference (RNAi) in the intestinal nematode Heligmosomoides polygyrus, we delivered double-stranded RNA (dsRNA) of tropomyosin to various life stages of the parasite. Three different methods were examined for their potential use. First, feeding of recombinant bacteria that expressed dsRNA did neither result in phenotypical changes of H. polygyrus nor in a significant reduction of tropomyosin mRNA levels. In contrast, feeding of such bacteria to Caenorhabditis elegans elicited the expected phenotypes. Quantification of bacteria ingested by C. elegans and H. polygyrus larvae (L1) revealed that the parasitic worms took up only a fraction of the bacteria ingested by C. elegans. Second, electroporation of L1 failed to transport siRNA through the cuticle and was lethal to the larvae. However, the cuticle of adult worms was penetrated by dye-labeled RNA, but no systemic spreading was observed. Third, soaking of adult H. polygyrus in tropomyosin dsRNA led to a higher proportion of worms showing symptoms of ageing, such as a disintegrated gut and ovaries, but did not induce reduction of tropomyosin mRNA levels. Database analysis revealed that orthologous proteins involved in dsRNA-uptake and -systemic spread in C. elegans are missing in the parasitic nematodes Brugia malayi and Haemonchus contortus, whereas proteins responsible for dsRNA-processing, -amplification and mRNA-regulation are present. Thus, our data indicate that the study of gene function by RNAi in H. polygyrus is limited, possibly due to deficiencies of genes involved in RNA-uptake and spread.

In vitro assessment of the influence of nutrition and temperature on growing rates of five Duddingtonia flagrans isolates, their insecticidal properties and ability to impair Heligmosomoides polygyrus motility.

Diverse effects of two temperature regimes (20 and 30 degrees C) on the growing rates of five Duddingtonia flagrans isolates (MUCL 28429, CBS 143.83, CBS 561.92, CBS 565.50, and CBS 583.91) propagated on two liquid (MM, LB) and four solid substrates (CMA, SAB, SAB-GM, and SAB-HP) were observed. All D. flagrans isolates were able to produce chlamydospores but not on all substrates. None of the isolates produced trapping nets and conidia under applied growing conditions. D. flagrans isolates showed moderate insecticidal properties against Galleria mellonella larvae with mortality rates below 20%. Preincubation (18 h) of Heligmosomoides polygyrus infective (L3) larvae in fungal homogenates highly impaired in vitro spontaneous motility of nematodes. This may indicate the potential of D. flagrans bioactive substance(s) for use as biocontrol agents of parasitic nematodes.