Exploring phosphoregulation of MYO3A using quantitative fluorescence image analysis in COS7 cells

Myosin 3A (MYO3A) is an unconventional myosin involved in the formation and maintenance of hair-cell stereocilia of the sensory epithelia in the inner ear. The kinase domain has been implicated in phosphoregulation of MYO3A activity through intermolecular autophosphorylation. Previous studies using mass spectrometry identified two potential phosphorylation sites in the motor domain. To investigate the regulatory roles of these sites, we generated glutamic acid point mutations in our mchr-MYO3A{Delta}K construct to mimic phosphorylation and assayed the constructs for their ability to tip-localize and influence filopodial density via transfection into COS7 cells. The phosphomimic constructs were less able to generate filopodia when compared to wildtype constructs. To gain a better understanding of the phosphoregulation of MYO3A, we transfected COS7 cells with mchr-MYO3A{Delta}K in combination with GFP-tagged full-length MYO3A (GFP-MYO3AFL), or GFP attached to just the kinase domain of MYO3A (GFP-MYO3AKIN). Coexpression of mchr-MYO3A{Delta}K with either construct resulted in decreased mchr-MYO3A levels at the tips of filopodia and fewer filopodia at the edge of the cell, compared to cells expressing mchr-MYO3A{Delta}K alone. This implies that the kinase domain does not require motor activity to contribute to phosphoregulation of MYO3A, and that MYO3A phosphoregulation may be influencing filopodia initiation. Informatic analyses and structural predictions suggest that the two phosphorylation sites in the motor domain inhibit actin/MYO3A interactions. Taken together, these analyses link MYO3A phosphorylation with the regulation of its ability to create actin protrusions such as filopodia and stereocilia.