Gouirand N, Mathew J, Brenner E, Danion FR. Eye movements do not play an important role in the adaptation of hand tracking to a visuomotor rotation. Adapting hand movements to changes in our body or the environment is essential for skilled motor behavior. Although eye movements are known to assist hand movement control, how eye movements might contribute to the adaptation of hand movements remains largely unexplored. To determine to what extent eye movements contribute to visuomotor adaptation of hand tracking, participants were asked to track a visual target that followed an unpredictable trajectory with a cursor using a joystick. During blocks of trials, participants were either allowed to look wherever they liked or required to fixate a cross at the center of the screen. Eye movements were tracked to ensure gaze fixation as well as to examine free gaze behavior. The cursor initially responded normally to the joystick, but after several trials, the direction in which it responded was rotated by 90°. Although fixating the eyes had a detrimental influence on hand tracking performance, participants exhibited a rather similar time course of adaptation to rotated visual feedback in the gaze-fixed and gaze-free conditions. More importantly, there was extensive transfer of adaptation between the gazefixed and gaze-free conditions. We conclude that although eye movements are relevant for the online control of hand tracking, they do not play an important role in the visuomotor adaptation of such tracking. These results suggest that participants do not adapt by changing the mapping between eye and hand movements, but rather by changing the mapping between hand movements and the cursor's motion independently of eye movements.NEW & NOTEWORTHY Eye movements assist hand movements in everyday activities, but their contribution to visuomotor adaptation remains largely unknown. We compared adaptation of hand tracking under free gaze and fixed gaze. Although our results confirm that following the target with the eyes increases the accuracy of hand movements, they unexpectedly demonstrate that gaze fixation does not hinder adaptation. These results suggest that eye movements have distinct contributions for online control and visuomotor adaptation of hand movements.
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SummarySeveral cellular processes during morphogenesis, tissue healing or cancer progression involve epithelial to mesenchymal plasticity that leads to collective motion (plasticity?). Even though a rich variety of EMP programs exist, a major hallmark unifying them is the initial breaking of symmetry that modifies the epithelial phenotype and axis of polarity. During this process, the actin cytoskeleton and cellular junctions are extensively remodelled correlating with the build-up of mechanical forces. As the collective migration proceeds, mechanical forces generated by the actin cytoskeleton align with the direction of migration ensuring an organized and efficient collective cell behaviour, but how forces are regulated during the breaking of symmetry at the onset of EMP remains an unaddressed question. It is known that the polarity complex CRB3/PALS1/PATJ, and in particular, CRB3 regulates the organization of the actin cytoskeleton associated to the apical domain thus pointing at a potential role of CRB3 in controlling mechanical forces. Whether and how CRB3 influences epithelial biomechanics during the epithelial-mesenchymal plasticity remains, however, largely unexplored. Here, we systematically combine mechanical and molecular analyses to show that CRB3 regulates the biomechanical properties of collective epithelial cells during the initial breaking of symmetry of the EMP. CRB3 interacts with ARP2/3 and controls the remodelling of actin throughout the monolayer via the modulation of the Rho-/Rac-GTPase balance. Taken together, our results identified CRB3, a polarity protein, as a regulator of epithelial monolayer mechanics during EMP.
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