Abstract Microsporidia are obligate intracellular parasites that infect a wide variety of hosts, including humans. Microsporidian spores possess a unique, highly specialized invasion apparatus involving the polar filament, polaroplast and posterior vacuole. During spore germination, the polar filament is discharged out of the spore forming the hollow polar tube that transports the sporoplasm components including nucleus into the host cell to achieve the invasion. Due to the complicated topological changes occurring in this process, the formation of sporoplasm is unclear. Here, electron microscopy observation and DiI staining confirmed that during spore germination, a large number of vesicles derived from the polaroplast, nucleus and other cytoplasm were transported out via the polar tube. Meanwhile, the posterior vacuole and plasma membrane remained in the empty spore coat. In addition, there was no DiI-labeled membrane around the nucleus in mature spores, whereas a DiI-labeled limit membrane wrapping nucleus was found at the tip of the extruded polar tube, suggesting that the membrane of sporoplasm was formed outside the mature spore. Two Nosema bombycis sporoplasm surface proteins (NbTMP1 and NoboABCG1.1) were located at the polaroplast in mature spores, in the extruded polar tube and on the sporoplasm membrane, which indicated that the polaroplast transported via the polar tube finally became the limiting membrane of the sporoplasm. Golgi-tracker green and Golgi marker protein syntaxin 6 were also found the same model, which was consistent with the transported polaroplast derived from Golgi transformed into the novel sporoplasm membrane during spore germination. Importance Microsporidia, obligate intracellular pathogenic organisms, cause huge economic losses in agriculture and even threaten human health. The key to successful infection of microsporidia is its unique invasion apparatus which includes the polar filament, polaroplast and posterior vacuole. When the spore is activated to geminate, the polar filament uncoils and undergoes a rapid transition into the hollow polar tube that will transport the sporoplasm components including nucleus into a host cell to achieve the invasion. Knowledge of structure difference between polar filament and polar tube, the process of cargo transport in extruded polar tube, and the formation of the sporoplasm membrane are still poorly understood. Herein, we verify that the polar filament evaginates to form the polar tube, which serves as a conduit for transporting elongated nucleus and other sporoplasm components. And we confirm that the transported polaroplast finally transforms into the novel sporoplasm membrane during spore germination. Our study provides new insights into the cargo transportation process of polar tube and origin of the sporoplasm membrane, which serve as foundations for clarifying the microsporidian infection mechanism.
