Abstract
Microsporidia are a group of obligated intracellular parasites that can infect nearly all vertebrates and invertebrates, including humans and economic animals. Microsporidian Vairimorpha necatrix is a natural pathogen of multiple insects and can massively proliferate by making tumor-like xenoma in host tissue. However, little is known about the subcellular structures of this xenoma and the proliferation features of the pathogens inside. Here, we characterized the V. necatrix xenoma produced in muscle cells of silkworm midgut. In result, the whitish xenoma was initially observed on the 12th day post infection on the outer surface of the midgut and later became larger and numerous. The observation by scanning electronic microscopy showed that the xenoma is mostly elliptical and spindle with dense pathogen-containing protrusions and spores on the surface, which were likely shedding off the xenoma through exocytosis and could be an infection source of other tissues. Demonstrated with transmission electron microscopy and fluorescent staining, the xenoma was enveloped by a monolayer membrane, and full of vesicle structures, mitochondria, and endoplasmic reticulum around parasites in development, suggesting that high level of energy and nutrients were produced to support the massive proliferation of the parasites. Multiple hypertrophic nuclei were found in one single xenoma, indicating that the cyst was probably formed by fusion of multiple muscle cells. Observed by fluorescence in situ hybridization, pathogens in the xenoma were in merongony, sporogony, and octosporogony, and mature stages. And mature spores were pushed to the center while vegetative pathogens were in the surface layer of the xenoma. The V. necatrix meront usually contained two to three nuclei, and sporont contained two nuclei and was wrapped by a thick membrane with high electron density. The V. necatrix sporogony produces two types of spores, the ordinary dikaryotic spore and unicellular octospores, the latter of which were smaller in size and packed in a sporophorous vesicle. In summary, V. necatrix xenoma is a specialized cyst likely formed by fusion of multiple muscle cells and provides high concentration of energy and nutrients with increased number of mitochondria and endoplasmic reticulum for the massive proliferation of pathogens inside.
Highlights
Microsporidia are obligate intracellular parasites and composed of at least 200 genera and 1,400 species (Fayer and Santin-Duran, 2014)
The midgut is the main digestive organ of silkworm, and the first organ infected by microsporidia
The xenomas grew larger, and the intestinal enlargement became evident on the 16th dpi
Summary
Microsporidia are obligate intracellular parasites and composed of at least 200 genera and 1,400 species (Fayer and Santin-Duran, 2014). Microsporidia can infect most animals, including humans and economically important animals like silkworm, bee, shrimp, crab, and fish (Franzen and Müller, 1999; Joseph et al, 2006). Most microsporidian infections usually cause no obvious tissue lesions, especially for those that can be vertically transmitted, while some species like Vairimorpha necatrix, Glugea arabica, Vavraia lutzomyiae, and Potaspora morhaphis can produce xenoma, which is a cyst full of pathogens and presents in many infected insects and aquatic animals (Lom and Dykova, 2005; Matos et al, 2006; Casal et al, 2008; Meng et al, 2018). Microsporidia and host cells interact and form a well-organize xenoparasitic complex, which was named “xenoma” by Weissenberg in 1949 (Lom and Dykova, 2005). Host nucleus undergoes amitosis to form many small nuclei, and host organelles increase significantly, including mitochondria and endoplasmic reticulum (ER) (Cali et al, 2012)
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