The parasitophorous vacuole of Encephalitozoon cuniculi: biogenesis and characteristics of the host cell-pathogen interface.

Microsporidia are obligate intracellular fungal pathogens of increasing importance in immunocompromised patients. They have developed a unique invasion mechanism, which is based on the explosive discharge of a hollow tubulus, the so-called polar tube. The infectious sporoplasm is subsequently extruded through this flexible tube and injected into the host cell. The model microsporidium Encephalitozoon cuniculi is a paradigm of a fungus with an extreme host cell dependency. This human pathogen possesses one of the smallest eukaryotic genomes (<3MB) identified so far and has reduced its own biosynthetic pathways to a minimum, thus depending on an efficient supply of metabolites from the host cell. E. cuniculi spends its entire intracellular life cycle inside a parasitophorous vacuole (PV), which is formed during invasion. We have provided here an overview of the biogenesis and characteristics of this important host cell-pathogen interface and suggest in this context a modified model for E. cuniculi invasion. According to the model, the host cell plasma membrane is not pierced by the polar tube, but is pushed at the contact site into the cell interior by the mechanical force of the expelled polar tube. This results in a channel-like invagination of the plasma membrane, from which finally the parasitophorous vacuole is pinched-off.

Germination of phagocytosed E. cuniculi spores does not significantly contribute to parasitophorous vacuole formation in J774 cells.

The obligate intracellular microsporidia have developed a unique invasion mechanism to infect their host cells. Spores explosively evert a tube-like structure and extrude the infectious spore content through this organelle into the host cell. Spores from species of the genus Encephalitozoon were also shown to be efficiently internalized by phagocytosis, which led to the hypothesis that spore germination from inside a phagosome might contribute to the infection process. Here, we challenge this hypothesis by quantifying Encephalitozoon cuniculi infection rates of J774 cells that were incubated with the phagocytosis inhibitor cytochalasin D. We demonstrate that the invasion rate in cytochalasin D-treated cells is identical to untreated controls, although phagocytic uptake of E. cuniculi spores was less than 10% of control samples. This study suggests that germination of phagocytosed spores is not a significant infection mode for E. cuniculi.