Organization of Myosin H in the Apical Complex of Toxoplasma Gondii Revealed by 3D Single-Molecule Super-Resolution Microscopy

Toxoplasma gondii is a single-celled eukaryotic parasite with prolific invasion capability. The parasite uses an apical complex comprised of proteinaceous structures and secretory organelles to efficiently enter host cells. As a result, the apical complex remains a vital structure of interest, with many studies dedicated to understanding its protein organization. One such protein is the motor Myosin H (MyoH), which is indispensable for parasite motility and host cell invasion. Given the small size of the complex, roughly a diffraction-limited volume in the visible, high-resolution techniques are required to make precise determinations of protein organization. In this work, we use 3D single-molecule localization microscopy in both traditionally fixed and gel-expanded parasites to localize the indispensable motor Myosin H within the apical complex. Labeling of the N- and C-terminus of MyoH in fixed parasites resolved the orientation of the motor protein in the apical complex, showing the motor head radially exterior to the tail. Two-color imaging of MyoH with tubulin in fixed parasites allowed for localization of the MyoH termini relative to the conoid, a barrel of tubulin-based fibers in the apical complex and showed the MyoH tail toward the interior face of the conoid and the head at the conoid exterior. Gel expansion showed improved labeling density for both tubulin and MyoH but altered MyoH localization, highlighting the nuanced effects of gel expansion on protein organization. Statement of SignificanceThis work employs 3D single-molecule super-resolution microscopy to provide quantitative physical analysis of the spatial organization of a vital myosin motor, MyoH, in the model apicomplexan parasite Toxoplasma gondii. While previous studies have provided high-resolution views of the parasites invasion machinery, MyoH has remained elusive at the nanoscale. We resolved differences in radial organization between the N- and C-termini of the motor, thus determining the orientation of the protein in the apical space. Two-color imaging revealed the organization of the motor in the greater context of the parasites invasion complex. 3D single-molecule imaging in gel-expanded samples revealed an increase in labeling efficiency but perturbed localization of only the MyoH C-terminus, highlighting the nuanced effects of gel expansion on protein organization.