Myo4p is a monomeric myosin with motility uniquely adapted to transport mRNA.

The yeast Saccharomyces cerevisiae uses two class V myosins to transport cellular material into the bud: Myo2p moves secretory vesicles and organelles, whereas Myo4p transports mRNA. To understand how Myo2p and Myo4p are adapted to transport physically distinct cargos, we characterize Myo2p and Myo4p in yeast extracts, purify active Myo2p and Myo4p from yeast lysates, and analyze their motility. We find several striking differences between Myo2p and Myo4p. First, Myo2p forms a dimer, whereas Myo4p is a monomer. Second, Myo4p generates higher actin filament velocity at lower motor density. Third, single molecules of Myo2p are weakly processive, whereas individual Myo4p motors are nonprocessive. Finally, Myo4p self-assembles into multi-motor complexes capable of processive motility. We show that the unique motility of Myo4p is not due to its motor domain and that the motor domain of Myo2p can transport ASH1 mRNA in vivo. Our results suggest that the oligomeric state of Myo4p is important for its motility and ability to transport mRNA.

Genetic control of neutrophil superoxide production in diabetes-resistant ALR/Lt mice.

The neutrophil oxidative burst reaction differentiates ALR/Lt mice, known for an unusual systemic elevation of antioxidant defenses, from ALS/Lt mice, a related strain known for reduced ability to withstand oxidative stress. Neutrophils from marrow of ALS mice produced a normal neutrophil oxidative burst following phorbol ester stimulation. In contrast, ALR mice exhibited a markedly suppressed superoxide burst. F1 progeny from reciprocal outcrosses between ALR and ALS mice exhibited an intermediate burst level, higher than ALR but significantly lower than ALS. To elucidate the genetic basis for this strain difference, F1 mice were backcrossed to ALS mice, and marrow neutrophils isolated from the progeny were phenotyped for oxidative burst capacity. A genome-wide sweep using polymorphic markers distinguishing the two parental strains was performed to map the trait. A 1:1 phenotypic distribution was observed, and a locus (Suppressor of superoxide production, Susp) controlling this phenotype was mapped to Chromosome 3 near D3Mit241 at 33.1 cM. This locus probably represents an important regulatory element in the overall ALR strain resistance to oxidative stress, since diminished ability to mount a neutrophil burst in backcross segregants correlated with elevated hepatic superoxide dismutase 1 (SOD1) activity, an ALR strain characteristic.

Myosin-X functions in polarized epithelial cells.

Myosin-X (Myo10) is an unconventional myosin that localizes to the tips of filopodia and has critical functions in filopodia. Although Myo10 has been studied primarily in nonpolarized, fibroblast-like cells, Myo10 is expressed in vivo in many epithelia-rich tissues, such as kidney. In this study, we investigate the localization and functions of Myo10 in polarized epithelial cells, using Madin-Darby canine kidney II cells as a model system. Calcium-switch experiments demonstrate that, during junction assembly, green fluorescent protein-Myo10 localizes to lateral membrane cell-cell contacts and to filopodia-like structures imaged by total internal reflection fluorescence on the basal surface. Knockdown of Myo10 leads to delayed recruitment of E-cadherin and ZO-1 to junctions, as well as a delay in tight junction barrier formation, as indicated by a delay in the development of peak transepithelial electrical resistance (TER). Although Myo10 knockdown cells eventually mature into monolayers with normal TER, these monolayers do exhibit increased paracellular permeability to fluorescent dextrans. Importantly, knockdown of Myo10 leads to mitotic spindle misorientation, and in three-dimensional culture, Myo10 knockdown cysts exhibit defects in lumen formation. Together these results reveal that Myo10 functions in polarized epithelial cells in junction formation, regulation of paracellular permeability, and epithelial morphogenesis.

A novel form of motility in filopodia revealed by imaging myosin-X at the single-molecule level.

Although many proteins, receptors, and viruses are transported rearward along filopodia by retrograde actin flow, it is less clear how molecules move forward in filopodia. Myosin-X (Myo10) is an actin-based motor hypothesized to use its motor activity to move forward along actin filaments to the tips of filopodia. Here we use a sensitive total internal reflection fluorescence (TIRF) microscopy system to directly visualize the movements of GFP-Myo10. This reveals a novel form of motility at or near the single-molecule level in living cells wherein extremely faint particles of Myo10 move in a rapid and directed fashion toward the filopodial tip. These fast forward movements occur at approximately 600 nm/s over distances of up to approximately 10 microm and require Myo10 motor activity and actin filaments. As expected for imaging at the single-molecule level, the faint particles of GFP-Myo10 are diffraction limited, have an intensity range similar to single GFP molecules, and exhibit stepwise bleaching. Faint particles of GFP-Myo5a can also move toward the filopodial tip, but at a slower characteristic velocity of approximately 250 nm/s. Similar movements were not detected with GFP-Myo1a, indicating that not all myosins are capable of intrafilopodial motility. These data indicate the existence of a novel system of long-range transport based on the rapid movement of myosin molecules along filopodial actin filaments.