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ABSTRACT Actin microfilaments (F-actin) serve as the track for directional movement of organelles in plant cells. In actively growing plant cells, F-actin often form robust bundles that trespass the cellular dimension. To test how the F-actin network was employed for peroxisome movement, we wished to disturb actin organization by genetically compromising the function of villin (VLN) proteins that serve as the primary bundling factor inArabidopsis thalianacells. To do so, we isolated T-DNA insertional mutants in threeVLNgenes that were most actively expressed in vegetative tissues. We found that thevln4mutation greatly enhanced the growth defects caused by thevln2 vln3double mutant as thevln2 vln3 vln4triple mutant had a great reduction of organ growth and formed heavily deformed tissues. Both VLN2 and VLN4 proteins were detected on bundled F-actin filaments. Compared to the wild-type cells, the double and triple mutants exhibited progressively reduction of stable F-actin bundles and had fine F-actin filaments undergo rapid remodeling. The defective F-actin network did not prevent peroxisomes from taking on both rapid and slow movements along the F-actin tracks. However, we found that compromised F-actin bundling caused significant reductions in the speed of peroxisome movement and the displacement distance of peroxisome positions. Using a correlation analysis method, we also demonstrated that the complex heterogeneous peroxisome movement may be classified into clusters reflecting the directionality of peroxisome movement. The triple mutant suffered from a significant reduction of peroxisomes exhibiting long-range and linear movement. Our results provided insights into how VLN-dependent F-actin organization was coupled with the complex patterns of peroxisome movement. 

Plant organelles predominantly rely on the actin cytoskeleton and the myosin motors for long-distance trafficking, while using microtubules and the kinesin motors mostly for short-range movement. The distribution and motility of organelles in the plant cell are fundamentally important to robust plant growth and defense. Chloroplasts, mitochondria, and peroxisomes are essential organelles in plants that function independently and coordinately during energy metabolism and other key metabolic processes. In response to developmental and environmental stimuli, these energy organelles modulate their metabolism, morphology, abundance, distribution and motility in the cell to meet the need of the plant. Consistent with their metabolic links in processes like photorespiration and fatty acid mobilization is the frequently observed inter-organellar physical interaction, sometimes through organelle membranous protrusions. The development of various organelle-specific fluorescent protein tags has allowed the simultaneous visualization of organelle movement in living plant cells by confocal microscopy. These energy organelles display an array of morphology and movement patterns and redistribute within the cell in response to changes such as varying light conditions, temperature fluctuations, ROS-inducible treatments, and during pollen tube development and immune response, independently or in association with one another. Although there are more reports on the mechanism of chloroplast movement than that of peroxisomes and mitochondria, our knowledge of how and why these three energy organelles move and distribute in the plant cell is still scarce at the functional and mechanistic level. It is critical to identify factors that control organelle motility coupled with plant growth, development, and stress response.